/* -*- indent-tabs-mode: nil; js-indent-level: 2 -*-*/ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ // You can direct about:memory to immediately load memory reports from a file // by providing a file= query string. For example, // // about:memory?file=/home/username/reports.json.gz // // "file=" is not case-sensitive. We'll URI-unescape the contents of the // "file=" argument, and obviously the filename is case-sensitive iff you're on // a case-sensitive filesystem. If you specify more than one "file=" argument, // only the first one is used. "use strict"; // --------------------------------------------------------------------------- var Cc = Components.classes; var Ci = Components.interfaces; var Cu = Components.utils; var CC = Components.Constructor; const KIND_NONHEAP = Ci.nsIMemoryReporter.KIND_NONHEAP; const KIND_HEAP = Ci.nsIMemoryReporter.KIND_HEAP; const KIND_OTHER = Ci.nsIMemoryReporter.KIND_OTHER; const UNITS_BYTES = Ci.nsIMemoryReporter.UNITS_BYTES; const UNITS_COUNT = Ci.nsIMemoryReporter.UNITS_COUNT; const UNITS_COUNT_CUMULATIVE = Ci.nsIMemoryReporter.UNITS_COUNT_CUMULATIVE; const UNITS_PERCENTAGE = Ci.nsIMemoryReporter.UNITS_PERCENTAGE; Cu.import("resource://gre/modules/Services.jsm"); Cu.import("resource://gre/modules/XPCOMUtils.jsm"); Cu.import("resource://gre/modules/NetUtil.jsm"); XPCOMUtils.defineLazyModuleGetter(this, "Downloads", "resource://gre/modules/Downloads.jsm"); XPCOMUtils.defineLazyModuleGetter(this, "FileUtils", "resource://gre/modules/FileUtils.jsm"); XPCOMUtils.defineLazyGetter(this, "nsBinaryStream", () => CC("@mozilla.org/binaryinputstream;1", "nsIBinaryInputStream", "setInputStream")); XPCOMUtils.defineLazyGetter(this, "nsFile", () => CC("@mozilla.org/file/local;1", "nsIFile", "initWithPath")); XPCOMUtils.defineLazyGetter(this, "nsGzipConverter", () => CC("@mozilla.org/streamconv;1?from=gzip&to=uncompressed", "nsIStreamConverter")); var gMgr = Cc["@mozilla.org/memory-reporter-manager;1"] .getService(Ci.nsIMemoryReporterManager); const gPageName = 'about:memory'; document.title = gPageName; const gUnnamedProcessStr = "Main Process"; var gIsDiff = false; // --------------------------------------------------------------------------- // Forward slashes in URLs in paths are represented with backslashes to avoid // being mistaken for path separators. Paths/names where this hasn't been // undone are prefixed with "unsafe"; the rest are prefixed with "safe". function flipBackslashes(aUnsafeStr) { // Save memory by only doing the replacement if it's necessary. return (aUnsafeStr.indexOf('\\') === -1) ? aUnsafeStr : aUnsafeStr.replace(/\\/g, '/'); } const gAssertionFailureMsgPrefix = "aboutMemory.js assertion failed: "; // This is used for things that should never fail, and indicate a defect in // this file if they do. function assert(aCond, aMsg) { if (!aCond) { reportAssertionFailure(aMsg) throw new Error(gAssertionFailureMsgPrefix + aMsg); } } // This is used for malformed input from memory reporters. function assertInput(aCond, aMsg) { if (!aCond) { throw new Error("Invalid memory report(s): " + aMsg); } } function handleException(ex) { let str = "" + ex; if (str.startsWith(gAssertionFailureMsgPrefix)) { // Argh, assertion failure within this file! Give up. throw ex; } else { // File or memory reporter problem. Print a message. updateMainAndFooter(str, HIDE_FOOTER, "badInputWarning"); } } function reportAssertionFailure(aMsg) { let debug = Cc["@mozilla.org/xpcom/debug;1"].getService(Ci.nsIDebug2); if (debug.isDebugBuild) { debug.assertion(aMsg, "false", "aboutMemory.js", 0); } } function debug(x) { let section = appendElement(document.body, 'div', 'section'); appendElementWithText(section, "div", "debug", JSON.stringify(x)); } // --------------------------------------------------------------------------- function onUnload() { } // --------------------------------------------------------------------------- // The
holding everything but the header and footer (if they're present). // It's what is updated each time the page changes. var gMain; // The
holding the footer. var gFooter; // The "verbose" checkbox. var gVerbose; // The "anonymize" checkbox. var gAnonymize; // Values for the |aFooterAction| argument to updateTitleMainAndFooter. var HIDE_FOOTER = 0; var SHOW_FOOTER = 1; function updateTitleMainAndFooter(aTitleNote, aMsg, aFooterAction, aClassName) { document.title = gPageName; if (aTitleNote) { document.title += " (" + aTitleNote + ")"; } // Clear gMain by replacing it with an empty node. let tmp = gMain.cloneNode(false); gMain.parentNode.replaceChild(tmp, gMain); gMain = tmp; gMain.classList.remove('hidden'); gMain.classList.remove('verbose'); gMain.classList.remove('non-verbose'); if (gVerbose) { gMain.classList.add(gVerbose.checked ? 'verbose' : 'non-verbose'); } let msgElement; if (aMsg) { let className = "section" if (aClassName) { className = className + " " + aClassName; } msgElement = appendElementWithText(gMain, 'div', className, aMsg); } switch (aFooterAction) { case HIDE_FOOTER: gFooter.classList.add('hidden'); break; case SHOW_FOOTER: gFooter.classList.remove('hidden'); break; default: assert(false, "bad footer action in updateTitleMainAndFooter"); } return msgElement; } function updateMainAndFooter(aMsg, aFooterAction, aClassName) { return updateTitleMainAndFooter("", aMsg, aFooterAction, aClassName); } function appendTextNode(aP, aText) { let e = document.createTextNode(aText); aP.appendChild(e); return e; } function appendElement(aP, aTagName, aClassName) { let e = document.createElement(aTagName); if (aClassName) { e.className = aClassName; } aP.appendChild(e); return e; } function appendElementWithText(aP, aTagName, aClassName, aText) { let e = appendElement(aP, aTagName, aClassName); // Setting textContent clobbers existing children, but there are none. More // importantly, it avoids creating a JS-land object for the node, saving // memory. e.textContent = aText; return e; } // --------------------------------------------------------------------------- const explicitTreeDescription = "This tree covers explicit memory allocations by the application. It includes \ \n\n\ * allocations made at the operating system level (via calls to functions such as \ VirtualAlloc, vm_allocate, and mmap), \ \n\n\ * allocations made at the heap allocation level (via functions such as malloc, \ calloc, realloc, memalign, operator new, and operator new[]) that have not been \ explicitly decommitted (i.e. evicted from memory and swap), and \ \n\n\ * where possible, the overhead of the heap allocator itself.\ \n\n\ It excludes memory that is mapped implicitly such as code and data segments, \ and thread stacks. \ \n\n\ 'explicit' is not guaranteed to cover every explicit allocation, but it does cover \ most (including the entire heap), and therefore it is the single best number to \ focus on when trying to reduce memory usage."; // --------------------------------------------------------------------------- function appendButton(aP, aTitle, aOnClick, aText, aId) { let b = appendElementWithText(aP, "button", "", aText); b.title = aTitle; b.onclick = aOnClick; if (aId) { b.id = aId; } return b; } function appendHiddenFileInput(aP, aId, aChangeListener) { let input = appendElementWithText(aP, "input", "hidden", ""); input.type = "file"; input.id = aId; // used in testing input.addEventListener("change", aChangeListener); return input; } function onLoad() { // Generate the header. let header = appendElement(document.body, "div", "ancillary"); // A hidden file input element that can be invoked when necessary. let fileInput1 = appendHiddenFileInput(header, "fileInput1", function() { let file = this.files[0]; let filename = file.mozFullPath; updateAboutMemoryFromFile(filename); }); // Ditto. let fileInput2 = appendHiddenFileInput(header, "fileInput2", function(e) { let file = this.files[0]; // First time around, we stash a copy of the filename and reinvoke. Second // time around we do the diff and display. if (!this.filename1) { this.filename1 = file.mozFullPath; // e.skipClick is only true when testing -- it allows fileInput2's // onchange handler to be re-called without having to go via the file // picker. if (!e.skipClick) { this.click(); } } else { let filename1 = this.filename1; delete this.filename1; updateAboutMemoryFromTwoFiles(filename1, file.mozFullPath); } }); const CuDesc = "Measure current memory reports and show."; const LdDesc = "Load memory reports from file and show."; const DfDesc = "Load memory report data from two files and show the " + "difference."; const SvDesc = "Save memory reports to file."; const GCDesc = "Do a global garbage collection."; const CCDesc = "Do a cycle collection."; const MMDesc = "Send three \"heap-minimize\" notifications in a " + "row. Each notification triggers a global garbage " + "collection followed by a cycle collection, and causes the " + "process to reduce memory usage in other ways, e.g. by " + "flushing various caches."; const GCAndCCLogDesc = "Save garbage collection log and concise cycle " + "collection log.\n" + "WARNING: These logs may be large (>1GB)."; const GCAndCCAllLogDesc = "Save garbage collection log and verbose cycle " + "collection log.\n" + "WARNING: These logs may be large (>1GB)."; const DMDEnabledDesc = "Analyze memory reports coverage and save the " + "output to the temp directory.\n"; const DMDDisabledDesc = "DMD is not running. Please re-start with $DMD and " + "the other relevant environment variables set " + "appropriately."; let ops = appendElement(header, "div", ""); let row1 = appendElement(ops, "div", "opsRow"); let labelDiv1 = appendElementWithText(row1, "div", "opsRowLabel", "Show memory reports"); let label1 = appendElementWithText(labelDiv1, "label", ""); gVerbose = appendElement(label1, "input", ""); gVerbose.type = "checkbox"; gVerbose.id = "verbose"; // used for testing appendTextNode(label1, "verbose"); const kEllipsis = "\u2026"; // The "measureButton" id is used for testing. appendButton(row1, CuDesc, doMeasure, "Measure", "measureButton"); appendButton(row1, LdDesc, () => fileInput1.click(), "Load" + kEllipsis); appendButton(row1, DfDesc, () => fileInput2.click(), "Load and diff" + kEllipsis); let row2 = appendElement(ops, "div", "opsRow"); let labelDiv2 = appendElementWithText(row2, "div", "opsRowLabel", "Save memory reports"); appendButton(row2, SvDesc, saveReportsToFile, "Measure and save" + kEllipsis); // XXX: this isn't a great place for this checkbox, but I can't think of // anywhere better. let label2 = appendElementWithText(labelDiv2, "label", ""); gAnonymize = appendElement(label2, "input", ""); gAnonymize.type = "checkbox"; appendTextNode(label2, "anonymize"); let row3 = appendElement(ops, "div", "opsRow"); appendElementWithText(row3, "div", "opsRowLabel", "Free memory"); appendButton(row3, GCDesc, doGC, "GC"); appendButton(row3, CCDesc, doCC, "CC"); appendButton(row3, MMDesc, doMMU, "Minimize memory usage"); let row4 = appendElement(ops, "div", "opsRow"); appendElementWithText(row4, "div", "opsRowLabel", "Save GC & CC logs"); appendButton(row4, GCAndCCLogDesc, saveGCLogAndConciseCCLog, "Save concise", 'saveLogsConcise'); appendButton(row4, GCAndCCAllLogDesc, saveGCLogAndVerboseCCLog, "Save verbose", 'saveLogsVerbose'); // Generate the main div, where content ("section" divs) will go. It's // hidden at first. gMain = appendElement(document.body, 'div', ''); gMain.id = 'mainDiv'; // Generate the footer. It's hidden at first. gFooter = appendElement(document.body, 'div', 'ancillary hidden'); let a = appendElementWithText(gFooter, "a", "option", "Troubleshooting information"); a.href = "about:support"; let legendText1 = "Click on a non-leaf node in a tree to expand ('++') " + "or collapse ('--') its children."; let legendText2 = "Hover the pointer over the name of a memory report " + "to see a description of what it measures."; appendElementWithText(gFooter, "div", "legend", legendText1); appendElementWithText(gFooter, "div", "legend hiddenOnMobile", legendText2); // See if we're loading from a file. (Because about:memory is a non-standard // URL, location.search is undefined, so we have to use location.href // instead.) let search = location.href.split('?')[1]; if (search) { let searchSplit = search.split('&'); for (let i = 0; i < searchSplit.length; i++) { if (searchSplit[i].toLowerCase().startsWith('file=')) { let filename = searchSplit[i].substring('file='.length); updateAboutMemoryFromFile(decodeURIComponent(filename)); return; } } } } // --------------------------------------------------------------------------- function doGC() { Services.obs.notifyObservers(null, "child-gc-request", null); Cu.forceGC(); updateMainAndFooter("Garbage collection completed", HIDE_FOOTER); } function doCC() { Services.obs.notifyObservers(null, "child-cc-request", null); window.QueryInterface(Ci.nsIInterfaceRequestor) .getInterface(Ci.nsIDOMWindowUtils) .cycleCollect(); updateMainAndFooter("Cycle collection completed", HIDE_FOOTER); } function doMMU() { Services.obs.notifyObservers(null, "child-mmu-request", null); gMgr.minimizeMemoryUsage( () => updateMainAndFooter("Memory minimization completed", HIDE_FOOTER)); } function doMeasure() { updateAboutMemoryFromReporters(); } function saveGCLogAndConciseCCLog() { dumpGCLogAndCCLog(false); } function saveGCLogAndVerboseCCLog() { dumpGCLogAndCCLog(true); } function doDMD() { updateMainAndFooter("Saving memory reports and DMD output...", HIDE_FOOTER); try { let dumper = Cc["@mozilla.org/memory-info-dumper;1"] .getService(Ci.nsIMemoryInfoDumper); dumper.dumpMemoryInfoToTempDir(/* identifier = */ "", gAnonymize.checked, /* minimize = */ false); updateMainAndFooter("Saved memory reports and DMD reports analysis " + "to the temp directory", HIDE_FOOTER); } catch (ex) { updateMainAndFooter(ex.toString(), HIDE_FOOTER); } } function dumpGCLogAndCCLog(aVerbose) { let dumper = Cc["@mozilla.org/memory-info-dumper;1"] .getService(Ci.nsIMemoryInfoDumper); let inProgress = updateMainAndFooter("Saving logs...", HIDE_FOOTER); let section = appendElement(gMain, 'div', "section"); function displayInfo(gcLog, ccLog, isParent) { appendElementWithText(section, 'div', "", "Saved GC log to " + gcLog.path); let ccLogType = aVerbose ? "verbose" : "concise"; appendElementWithText(section, 'div', "", "Saved " + ccLogType + " CC log to " + ccLog.path); } dumper.dumpGCAndCCLogsToFile("", aVerbose, /* dumpChildProcesses = */ true, { onDump: displayInfo, onFinish: function() { inProgress.remove(); } }); } /** * Top-level function that does the work of generating the page from the memory * reporters. */ function updateAboutMemoryFromReporters() { updateMainAndFooter("Measuring...", HIDE_FOOTER); try { let processLiveMemoryReports = function(aHandleReport, aDisplayReports) { let handleReport = function(aProcess, aUnsafePath, aKind, aUnits, aAmount, aDescription) { aHandleReport(aProcess, aUnsafePath, aKind, aUnits, aAmount, aDescription, /* presence = */ undefined); } let displayReportsAndFooter = function() { updateTitleMainAndFooter("live measurement", "", SHOW_FOOTER); aDisplayReports(); } gMgr.getReports(handleReport, null, displayReportsAndFooter, null, gAnonymize.checked); } // Process the reports from the live memory reporters. appendAboutMemoryMain(processLiveMemoryReports, gMgr.hasMozMallocUsableSize); } catch (ex) { handleException(ex); } } // Increment this if the JSON format changes. // var gCurrentFileFormatVersion = 1; /** * Parse a string as JSON and extract the |memory_report| property if it has * one, which indicates the string is from a crash dump. * * @param aStr * The string. * @return The extracted object. */ function parseAndUnwrapIfCrashDump(aStr) { let obj = JSON.parse(aStr); if (obj.memory_report !== undefined) { // It looks like a crash dump. The memory reports should be in the // |memory_report| property. obj = obj.memory_report; } return obj; } /** * Populate about:memory using the data in the given JSON object. * * @param aObj * An object that (hopefully!) conforms to the JSON schema used by * nsIMemoryInfoDumper. */ function updateAboutMemoryFromJSONObject(aObj) { try { assertInput(aObj.version === gCurrentFileFormatVersion, "data version number missing or doesn't match"); assertInput(aObj.hasMozMallocUsableSize !== undefined, "missing 'hasMozMallocUsableSize' property"); assertInput(aObj.reports && aObj.reports instanceof Array, "missing or non-array 'reports' property"); let processMemoryReportsFromFile = function(aHandleReport, aDisplayReports) { for (let i = 0; i < aObj.reports.length; i++) { let r = aObj.reports[i]; // A hack: for a brief time (late in the FF26 and early in the FF27 // cycle) we were dumping memory report files that contained reports // whose path began with "redundant/". Such reports were ignored by // about:memory. These reports are no longer produced, but some older // builds are still floating around and producing files that contain // them, so we need to still handle them (i.e. ignore them). This hack // can be removed once FF26 and associated products (e.g. B2G 1.2) are // no longer in common use. if (!r.path.startsWith("redundant/")) { aHandleReport(r.process, r.path, r.kind, r.units, r.amount, r.description, r._presence); } } aDisplayReports(); } appendAboutMemoryMain(processMemoryReportsFromFile, aObj.hasMozMallocUsableSize); } catch (ex) { handleException(ex); } } /** * Populate about:memory using the data in the given JSON string. * * @param aStr * A string containing JSON data conforming to the schema used by * nsIMemoryReporterManager::dumpReports. */ function updateAboutMemoryFromJSONString(aStr) { try { let obj = parseAndUnwrapIfCrashDump(aStr); updateAboutMemoryFromJSONObject(obj); } catch (ex) { handleException(ex); } } /** * Loads the contents of a file into a string and passes that to a callback. * * @param aFilename * The name of the file being read from. * @param aTitleNote * A description to put in the page title upon completion. * @param aFn * The function to call and pass the read string to upon completion. */ function loadMemoryReportsFromFile(aFilename, aTitleNote, aFn) { updateMainAndFooter("Loading...", HIDE_FOOTER); try { let reader = new FileReader(); reader.onerror = () => { throw new Error("FileReader.onerror"); }; reader.onabort = () => { throw new Error("FileReader.onabort"); }; reader.onload = (aEvent) => { // Clear "Loading..." from above. updateTitleMainAndFooter(aTitleNote, "", SHOW_FOOTER); aFn(aEvent.target.result); }; // If it doesn't have a .gz suffix, read it as a (legacy) ungzipped file. if (!aFilename.endsWith(".gz")) { reader.readAsText(File.createFromFileName(aFilename)); return; } // Read compressed gzip file. let converter = new nsGzipConverter(); converter.asyncConvertData("gzip", "uncompressed", { data: [], onStartRequest: function(aR, aC) {}, onDataAvailable: function(aR, aC, aStream, aO, aCount) { let bi = new nsBinaryStream(aStream); this.data.push(bi.readBytes(aCount)); }, onStopRequest: function(aR, aC, aStatusCode) { try { if (!Components.isSuccessCode(aStatusCode)) { throw new Components.Exception("Error while reading gzip file", aStatusCode); } reader.readAsText(new Blob(this.data)); } catch (ex) { handleException(ex); } } }, null); let file = new nsFile(aFilename); let fileChan = NetUtil.newChannel({ uri: Services.io.newFileURI(file), loadUsingSystemPrincipal: true }); fileChan.asyncOpen2(converter); } catch (ex) { handleException(ex); } } /** * Like updateAboutMemoryFromReporters(), but gets its data from a file instead * of the memory reporters. * * @param aFilename * The name of the file being read from. The expected format of the * file's contents is described in a comment in nsIMemoryInfoDumper.idl. */ function updateAboutMemoryFromFile(aFilename) { loadMemoryReportsFromFile(aFilename, /* title note */ aFilename, updateAboutMemoryFromJSONString); } /** * Like updateAboutMemoryFromFile(), but gets its data from a two files and * diffs them. * * @param aFilename1 * The name of the first file being read from. * @param aFilename2 * The name of the first file being read from. */ function updateAboutMemoryFromTwoFiles(aFilename1, aFilename2) { let titleNote = "diff of " + aFilename1 + " and " + aFilename2; loadMemoryReportsFromFile(aFilename1, titleNote, function(aStr1) { loadMemoryReportsFromFile(aFilename2, titleNote, function(aStr2) { try { let obj1 = parseAndUnwrapIfCrashDump(aStr1); let obj2 = parseAndUnwrapIfCrashDump(aStr2); gIsDiff = true; updateAboutMemoryFromJSONObject(diffJSONObjects(obj1, obj2)); gIsDiff = false; } catch (ex) { handleException(ex); } }); }); } // --------------------------------------------------------------------------- // Something unlikely to appear in a process name. var kProcessPathSep = "^:^:^"; // Short for "diff report". function DReport(aKind, aUnits, aAmount, aDescription, aNMerged, aPresence) { this._kind = aKind; this._units = aUnits; this._amount = aAmount; this._description = aDescription; this._nMerged = aNMerged; if (aPresence !== undefined) { this._presence = aPresence; } } DReport.prototype = { assertCompatible: function(aKind, aUnits) { assert(this._kind == aKind, "Mismatched kinds"); assert(this._units == aUnits, "Mismatched units"); // We don't check that the "description" properties match. This is because // on Linux we can get cases where the paths are the same but the // descriptions differ, like this: // // "path": "size/other-files/icon-theme.cache/[r--p]", // "description": "/usr/share/icons/gnome/icon-theme.cache (read-only, not executable, private)" // // "path": "size/other-files/icon-theme.cache/[r--p]" // "description": "/usr/share/icons/hicolor/icon-theme.cache (read-only, not executable, private)" // // In those cases, we just use the description from the first-encountered // one, which is what about:memory also does. // (Note: reports with those paths are no longer generated, but allowing // the descriptions to differ seems reasonable.) }, merge: function(aJr) { this.assertCompatible(aJr.kind, aJr.units); this._amount += aJr.amount; this._nMerged++; }, toJSON: function(aProcess, aPath, aAmount) { return { process: aProcess, path: aPath, kind: this._kind, units: this._units, amount: aAmount, description: this._description, _presence: this._presence }; } }; // Constants that indicate if a DReport was present only in one of the data // sets, or had to be added for balance. DReport.PRESENT_IN_FIRST_ONLY = 1; DReport.PRESENT_IN_SECOND_ONLY = 2; DReport.ADDED_FOR_BALANCE = 3; /** * Make a report map, which has combined path+process strings for keys, and * DReport objects for values. * * @param aJSONReports * The |reports| field of a JSON object. * @return The constructed report map. */ function makeDReportMap(aJSONReports) { let dreportMap = {}; for (let i = 0; i < aJSONReports.length; i++) { let jr = aJSONReports[i]; assert(jr.process !== undefined, "Missing process"); assert(jr.path !== undefined, "Missing path"); assert(jr.kind !== undefined, "Missing kind"); assert(jr.units !== undefined, "Missing units"); assert(jr.amount !== undefined, "Missing amount"); assert(jr.description !== undefined, "Missing description"); // Strip out some non-deterministic stuff that prevents clean diffs. // Ideally the memory reports themselves would contain information about // which parts of the the process and path need to be stripped -- saving us // from hardwiring knowledge of specific reporters here -- but we have no // mechanism for that. (Any future redesign of how memory reporters work // should include such a mechanism.) // Strip PIDs: // - pid 123 // - pid=123 let pidRegex = /pid([ =])\d+/g; let pidSubst = "pid$1NNN"; let process = jr.process.replace(pidRegex, pidSubst); let path = jr.path.replace(pidRegex, pidSubst); // Strip addresses: // - .../js-zone(0x12345678)/... // - .../zone(0x12345678)/... // - .../worker(, 0x12345678)/... path = path.replace(/zone\(0x[0-9A-Fa-f]+\)\//, "zone(0xNNN)/"); path = path.replace(/\/worker\((.+), 0x[0-9A-Fa-f]+\)\//, "/worker($1, 0xNNN)/"); // Strip top window IDs: // - explicit/window-objects/top(, id=123)/... path = path.replace(/^(explicit\/window-objects\/top\(.*, id=)\d+\)/, "$1NNN)"); // Strip null principal UUIDs (but not other UUIDs, because they may be // deterministic, such as those used by add-ons). path = path.replace( /moz-nullprincipal:{........-....-....-....-............}/g, "moz-nullprincipal:{NNNNNNNN-NNNN-NNNN-NNNN-NNNNNNNNNNNN}"); // Normalize omni.ja! paths. path = path.replace(/jar:file:\\\\\\(.+)\\omni.ja!/, "jar:file:\\\\\\...\\omni.ja!"); let processPath = process + kProcessPathSep + path; let rOld = dreportMap[processPath]; if (rOld === undefined) { dreportMap[processPath] = new DReport(jr.kind, jr.units, jr.amount, jr.description, 1, undefined); } else { rOld.merge(jr); } } return dreportMap; } // Return a new dreportMap which is the diff of two dreportMaps. Empties // aDReportMap2 along the way. function diffDReportMaps(aDReportMap1, aDReportMap2) { let result = {}; for (let processPath in aDReportMap1) { let r1 = aDReportMap1[processPath]; let r2 = aDReportMap2[processPath]; let r2_amount, r2_nMerged; let presence; if (r2 !== undefined) { r1.assertCompatible(r2._kind, r2._units); r2_amount = r2._amount; r2_nMerged = r2._nMerged; delete aDReportMap2[processPath]; presence = undefined; // represents that it's present in both } else { r2_amount = 0; r2_nMerged = 0; presence = DReport.PRESENT_IN_FIRST_ONLY; } result[processPath] = new DReport(r1._kind, r1._units, r2_amount - r1._amount, r1._description, Math.max(r1._nMerged, r2_nMerged), presence); } for (let processPath in aDReportMap2) { let r2 = aDReportMap2[processPath]; result[processPath] = new DReport(r2._kind, r2._units, r2._amount, r2._description, r2._nMerged, DReport.PRESENT_IN_SECOND_ONLY); } return result; } function makeJSONReports(aDReportMap) { let reports = []; for (let processPath in aDReportMap) { let r = aDReportMap[processPath]; if (r._amount !== 0) { // If _nMerged > 1, we give the full (aggregated) amount in the first // copy, and then use amount=0 in the remainder. When viewed in // about:memory, this shows up as an entry with a "[2]"-style suffix // and the correct amount. let split = processPath.split(kProcessPathSep); assert(split.length >= 2); let process = split.shift(); let path = split.join(); reports.push(r.toJSON(process, path, r._amount)); for (let i = 1; i < r._nMerged; i++) { reports.push(r.toJSON(process, path, 0)); } } } return reports; } // Diff two JSON objects holding memory reports. function diffJSONObjects(aJson1, aJson2) { function simpleProp(aProp) { assert(aJson1[aProp] !== undefined && aJson1[aProp] === aJson2[aProp], aProp + " properties don't match"); return aJson1[aProp]; } return { version: simpleProp("version"), hasMozMallocUsableSize: simpleProp("hasMozMallocUsableSize"), reports: makeJSONReports(diffDReportMaps(makeDReportMap(aJson1.reports), makeDReportMap(aJson2.reports))) }; } // --------------------------------------------------------------------------- // |PColl| is short for "process collection". function PColl() { this._trees = {}; this._degenerates = {}; this._heapTotal = 0; } /** * Processes reports (whether from reporters or from a file) and append the * main part of the page. * * @param aProcessReports * Function that extracts the memory reports from the reporters or from * file. * @param aHasMozMallocUsableSize * Boolean indicating if moz_malloc_usable_size works. */ function appendAboutMemoryMain(aProcessReports, aHasMozMallocUsableSize) { let pcollsByProcess = {}; function handleReport(aProcess, aUnsafePath, aKind, aUnits, aAmount, aDescription, aPresence) { if (aUnsafePath.startsWith("explicit/")) { assertInput(aKind === KIND_HEAP || aKind === KIND_NONHEAP, "bad explicit kind"); assertInput(aUnits === UNITS_BYTES, "bad explicit units"); } assert(aPresence === undefined || aPresence == DReport.PRESENT_IN_FIRST_ONLY || aPresence == DReport.PRESENT_IN_SECOND_ONLY, "bad presence"); let process = aProcess === "" ? gUnnamedProcessStr : aProcess; let unsafeNames = aUnsafePath.split('/'); let unsafeName0 = unsafeNames[0]; let isDegenerate = unsafeNames.length === 1; // Get the PColl table for the process, creating it if necessary. let pcoll = pcollsByProcess[process]; if (!pcollsByProcess[process]) { pcoll = pcollsByProcess[process] = new PColl(); } // Get the root node, creating it if necessary. let psubcoll = isDegenerate ? pcoll._degenerates : pcoll._trees; let t = psubcoll[unsafeName0]; if (!t) { t = psubcoll[unsafeName0] = new TreeNode(unsafeName0, aUnits, isDegenerate); } if (!isDegenerate) { // Add any missing nodes in the tree implied by aUnsafePath, and fill in // the properties that we can with a top-down traversal. for (let i = 1; i < unsafeNames.length; i++) { let unsafeName = unsafeNames[i]; let u = t.findKid(unsafeName); if (!u) { u = new TreeNode(unsafeName, aUnits, isDegenerate); if (!t._kids) { t._kids = []; } t._kids.push(u); } t = u; } // Update the heap total if necessary. if (unsafeName0 === "explicit" && aKind == KIND_HEAP) { pcollsByProcess[process]._heapTotal += aAmount; } } if (t._amount) { // Duplicate! Sum the values and mark it as a dup. t._amount += aAmount; t._nMerged = t._nMerged ? t._nMerged + 1 : 2; assert(t._presence === aPresence, "presence mismatch"); } else { // New leaf node. Fill in extra node details from the report. t._amount = aAmount; t._description = aDescription; if (aPresence !== undefined) { t._presence = aPresence; } } } function displayReports() { // Sort the processes. let processes = Object.keys(pcollsByProcess); processes.sort(function(aProcessA, aProcessB) { assert(aProcessA != aProcessB, "Elements of Object.keys() should be unique, but " + "saw duplicate '" + aProcessA + "' elem."); // Always put the main process first. if (aProcessA == gUnnamedProcessStr) { return -1; } if (aProcessB == gUnnamedProcessStr) { return 1; } // Then sort by resident size. let nodeA = pcollsByProcess[aProcessA]._degenerates['resident']; let nodeB = pcollsByProcess[aProcessB]._degenerates['resident']; let residentA = nodeA ? nodeA._amount : -1; let residentB = nodeB ? nodeB._amount : -1; if (residentA > residentB) { return -1; } if (residentA < residentB) { return 1; } // Then sort by process name. if (aProcessA < aProcessB) { return -1; } if (aProcessA > aProcessB) { return 1; } return 0; }); // Generate output for each process. for (let i = 0; i < processes.length; i++) { let process = processes[i]; let section = appendElement(gMain, 'div', 'section'); appendProcessAboutMemoryElements(section, i, process, pcollsByProcess[process]._trees, pcollsByProcess[process]._degenerates, pcollsByProcess[process]._heapTotal, aHasMozMallocUsableSize); } } aProcessReports(handleReport, displayReports); } // --------------------------------------------------------------------------- // There are two kinds of TreeNode. // - Leaf TreeNodes correspond to reports. // - Non-leaf TreeNodes are just scaffolding nodes for the tree; their values // are derived from their children. // Some trees are "degenerate", i.e. they contain a single node, i.e. they // correspond to a report whose path has no '/' separators. function TreeNode(aUnsafeName, aUnits, aIsDegenerate) { this._units = aUnits; this._unsafeName = aUnsafeName; if (aIsDegenerate) { this._isDegenerate = true; } // Leaf TreeNodes have these properties added immediately after construction: // - _amount // - _description // - _nMerged (only defined if > 1) // - _presence (only defined if value is PRESENT_IN_{FIRST,SECOND}_ONLY) // // Non-leaf TreeNodes have these properties added later: // - _kids // - _amount // - _description // - _hideKids (only defined if true) // - _maxAbsDescendant (on-demand, only when gIsDiff is set) } TreeNode.prototype = { findKid: function(aUnsafeName) { if (this._kids) { for (let i = 0; i < this._kids.length; i++) { if (this._kids[i]._unsafeName === aUnsafeName) { return this._kids[i]; } } } return undefined; }, // When gIsDiff is false, tree operations -- sorting and determining if a // sub-tree is significant -- are straightforward. But when gIsDiff is true, // the combination of positive and negative values within a tree complicates // things. So for a non-leaf node, instead of just looking at _amount, we // instead look at the maximum absolute value of the node and all of its // descendants. maxAbsDescendant: function() { if (!this._kids) { // No kids? Just return the absolute value of the amount. return Math.abs(this._amount); } if ('_maxAbsDescendant' in this) { // We've computed this before? Return the saved value. return this._maxAbsDescendant; } // Compute the maximum absolute value of all descendants. let max = Math.abs(this._amount); for (let i = 0; i < this._kids.length; i++) { max = Math.max(max, this._kids[i].maxAbsDescendant()); } this._maxAbsDescendant = max; return max; }, toString: function() { switch (this._units) { case UNITS_BYTES: return formatBytes(this._amount); case UNITS_COUNT: case UNITS_COUNT_CUMULATIVE: return formatInt(this._amount); case UNITS_PERCENTAGE: return formatPercentage(this._amount); default: throw "Invalid memory report(s): bad units in TreeNode.toString"; } } }; // Sort TreeNodes first by size, then by name. The latter is important for the // about:memory tests, which need a predictable ordering of reporters which // have the same amount. TreeNode.compareAmounts = function(aA, aB) { let a, b; if (gIsDiff) { a = aA.maxAbsDescendant(); b = aB.maxAbsDescendant(); } else { a = aA._amount; b = aB._amount; } if (a > b) { return -1; } if (a < b) { return 1; } return TreeNode.compareUnsafeNames(aA, aB); }; TreeNode.compareUnsafeNames = function(aA, aB) { return aA._unsafeName.localeCompare(aB._unsafeName); }; /** * Fill in the remaining properties for the specified tree in a bottom-up * fashion. * * @param aRoot * The tree root. */ function fillInTree(aRoot) { // Fill in the remaining properties bottom-up. function fillInNonLeafNodes(aT) { if (!aT._kids) { // Leaf node. Has already been filled in. } else if (aT._kids.length === 1 && aT != aRoot) { // Non-root, non-leaf node with one child. Merge the child with the node // to avoid redundant entries. let kid = aT._kids[0]; let kidBytes = fillInNonLeafNodes(kid); aT._unsafeName += '/' + kid._unsafeName; if (kid._kids) { aT._kids = kid._kids; } else { delete aT._kids; } aT._amount = kidBytes; aT._description = kid._description; if (kid._nMerged !== undefined) { aT._nMerged = kid._nMerged } assert(!aT._hideKids && !kid._hideKids, "_hideKids set when merging"); } else { // Non-leaf node with multiple children. Derive its _amount and // _description entirely from its children... let kidsBytes = 0; for (let i = 0; i < aT._kids.length; i++) { kidsBytes += fillInNonLeafNodes(aT._kids[i]); } // ... except in one special case. When diffing two memory report sets, // if one set has a node with children and the other has the same node // but without children -- e.g. the first has "a/b/c" and "a/b/d", but // the second only has "a/b" -- we need to add a fake node "a/b/(fake)" // to the second to make the trees comparable. It's ugly, but it works. if (aT._amount !== undefined && (aT._presence === DReport.PRESENT_IN_FIRST_ONLY || aT._presence === DReport.PRESENT_IN_SECOND_ONLY)) { aT._amount += kidsBytes; let fake = new TreeNode('(fake child)', aT._units); fake._presence = DReport.ADDED_FOR_BALANCE; fake._amount = aT._amount - kidsBytes; aT._kids.push(fake); delete aT._presence; } else { assert(aT._amount === undefined, "_amount already set for non-leaf node") aT._amount = kidsBytes; } aT._description = "The sum of all entries below this one."; } return aT._amount; } // cannotMerge is set because don't want to merge into a tree's root node. fillInNonLeafNodes(aRoot); } /** * Compute the "heap-unclassified" value and insert it into the "explicit" * tree. * * @param aT * The "explicit" tree. * @param aHeapAllocatedNode * The "heap-allocated" tree node. * @param aHeapTotal * The sum of all explicit HEAP reports for this process. * @return A boolean indicating if "heap-allocated" is known for the process. */ function addHeapUnclassifiedNode(aT, aHeapAllocatedNode, aHeapTotal) { if (aHeapAllocatedNode === undefined) return false; if (aT.findKid("heap-unclassified")) { // heap-unclassified was already calculated, there's nothing left to do. // This can happen when memory reports are exported from areweslimyet.com. return true; } assert(aHeapAllocatedNode._isDegenerate, "heap-allocated is not degenerate"); let heapAllocatedBytes = aHeapAllocatedNode._amount; let heapUnclassifiedT = new TreeNode("heap-unclassified", UNITS_BYTES); heapUnclassifiedT._amount = heapAllocatedBytes - aHeapTotal; heapUnclassifiedT._description = "Memory not classified by a more specific report. This includes " + "slop bytes due to internal fragmentation in the heap allocator " + "(caused when the allocator rounds up request sizes)."; aT._kids.push(heapUnclassifiedT); aT._amount += heapUnclassifiedT._amount; return true; } /** * Sort all kid nodes from largest to smallest, and insert aggregate nodes * where appropriate. * * @param aTotalBytes * The size of the tree's root node. * @param aT * The tree. */ function sortTreeAndInsertAggregateNodes(aTotalBytes, aT) { const kSignificanceThresholdPerc = 1; function isInsignificant(aT) { if (gVerbose.checked) return false; let perc = gIsDiff ? 100 * aT.maxAbsDescendant() / Math.abs(aTotalBytes) : 100 * aT._amount / aTotalBytes; return perc < kSignificanceThresholdPerc; } if (!aT._kids) { return; } aT._kids.sort(TreeNode.compareAmounts); // If the first child is insignificant, they all are, and there's no point // creating an aggregate node that lacks siblings. Just set the parent's // _hideKids property and process all children. if (isInsignificant(aT._kids[0])) { aT._hideKids = true; for (let i = 0; i < aT._kids.length; i++) { sortTreeAndInsertAggregateNodes(aTotalBytes, aT._kids[i]); } return; } // Look at all children except the last one. let i; for (i = 0; i < aT._kids.length - 1; i++) { if (isInsignificant(aT._kids[i])) { // This child is below the significance threshold. If there are other // (smaller) children remaining, move them under an aggregate node. let i0 = i; let nAgg = aT._kids.length - i0; // Create an aggregate node. Inherit units from the parent; everything // in the tree should have the same units anyway (we test this later). let aggT = new TreeNode("(" + nAgg + " tiny)", aT._units); aggT._kids = []; let aggBytes = 0; for ( ; i < aT._kids.length; i++) { aggBytes += aT._kids[i]._amount; aggT._kids.push(aT._kids[i]); } aggT._hideKids = true; aggT._amount = aggBytes; aggT._description = nAgg + " sub-trees that are below the " + kSignificanceThresholdPerc + "% significance threshold."; aT._kids.splice(i0, nAgg, aggT); aT._kids.sort(TreeNode.compareAmounts); // Process the moved children. for (i = 0; i < aggT._kids.length; i++) { sortTreeAndInsertAggregateNodes(aTotalBytes, aggT._kids[i]); } return; } sortTreeAndInsertAggregateNodes(aTotalBytes, aT._kids[i]); } // The first n-1 children were significant. Don't consider if the last child // is significant; there's no point creating an aggregate node that only has // one child. Just process it. sortTreeAndInsertAggregateNodes(aTotalBytes, aT._kids[i]); } // Global variable indicating if we've seen any invalid values for this // process; it holds the unsafePaths of any such reports. It is reset for // each new process. var gUnsafePathsWithInvalidValuesForThisProcess = []; function appendWarningElements(aP, aHasKnownHeapAllocated, aHasMozMallocUsableSize) { if (!aHasKnownHeapAllocated && !aHasMozMallocUsableSize) { appendElementWithText(aP, "p", "", "WARNING: the 'heap-allocated' memory reporter and the " + "moz_malloc_usable_size() function do not work for this platform " + "and/or configuration. This means that 'heap-unclassified' is not " + "shown and the 'explicit' tree shows much less memory than it should.\n\n"); } else if (!aHasKnownHeapAllocated) { appendElementWithText(aP, "p", "", "WARNING: the 'heap-allocated' memory reporter does not work for this " + "platform and/or configuration. This means that 'heap-unclassified' " + "is not shown and the 'explicit' tree shows less memory than it should.\n\n"); } else if (!aHasMozMallocUsableSize) { appendElementWithText(aP, "p", "", "WARNING: the moz_malloc_usable_size() function does not work for " + "this platform and/or configuration. This means that much of the " + "heap-allocated memory is not measured by individual memory reporters " + "and so will fall under 'heap-unclassified'.\n\n"); } if (gUnsafePathsWithInvalidValuesForThisProcess.length > 0) { let div = appendElement(aP, "div"); appendElementWithText(div, "p", "", "WARNING: the following values are negative or unreasonably large.\n"); let ul = appendElement(div, "ul"); for (let i = 0; i < gUnsafePathsWithInvalidValuesForThisProcess.length; i++) { appendTextNode(ul, " "); appendElementWithText(ul, "li", "", flipBackslashes(gUnsafePathsWithInvalidValuesForThisProcess[i]) + "\n"); } appendElementWithText(div, "p", "", "This indicates a defect in one or more memory reporters. The " + "invalid values are highlighted.\n\n"); gUnsafePathsWithInvalidValuesForThisProcess = []; // reset for the next process } } /** * Appends the about:memory elements for a single process. * * @param aP * The parent DOM node. * @param aN * The number of the process, starting at 0. * @param aProcess * The name of the process. * @param aTrees * The table of non-degenerate trees for this process. * @param aDegenerates * The table of degenerate trees for this process. * @param aHasMozMallocUsableSize * Boolean indicating if moz_malloc_usable_size works. * @return The generated text. */ function appendProcessAboutMemoryElements(aP, aN, aProcess, aTrees, aDegenerates, aHeapTotal, aHasMozMallocUsableSize) { const kUpwardsArrow = "\u2191", kDownwardsArrow = "\u2193"; let appendLink = function(aHere, aThere, aArrow) { let link = appendElementWithText(aP, "a", "upDownArrow", aArrow); link.href = "#" + aThere + aN; link.id = aHere + aN; link.title = "Go to the " + aThere + " of " + aProcess; link.style = "text-decoration: none"; // This jumps to the anchor without the page location getting the anchor // name tacked onto its end, which is what happens with a vanilla link. link.addEventListener("click", function(event) { document.documentElement.scrollTop = document.querySelector(event.target.href).offsetTop; event.preventDefault(); }, false); // This gives nice spacing when we copy and paste. appendElementWithText(aP, "span", "", "\n"); } appendElementWithText(aP, "h1", "", aProcess); appendLink("start", "end", kDownwardsArrow); // We'll fill this in later. let warningsDiv = appendElement(aP, "div", "accuracyWarning"); // The explicit tree. let hasExplicitTree; let hasKnownHeapAllocated; { let treeName = "explicit"; let t = aTrees[treeName]; if (t) { let pre = appendSectionHeader(aP, "Explicit Allocations"); hasExplicitTree = true; fillInTree(t); // Using the "heap-allocated" reporter here instead of // nsMemoryReporterManager.heapAllocated goes against the usual pattern. // But the "heap-allocated" node will go in the tree like the others, so // we have to deal with it, and once we're dealing with it, it's easier // to keep doing so rather than switching to the distinguished amount. hasKnownHeapAllocated = aDegenerates && addHeapUnclassifiedNode(t, aDegenerates["heap-allocated"], aHeapTotal); sortTreeAndInsertAggregateNodes(t._amount, t); t._description = explicitTreeDescription; appendTreeElements(pre, t, aProcess, ""); delete aTrees[treeName]; } appendTextNode(aP, "\n"); // gives nice spacing when we copy and paste } // Fill in and sort all the non-degenerate other trees. let otherTrees = []; for (let unsafeName in aTrees) { let t = aTrees[unsafeName]; assert(!t._isDegenerate, "tree is degenerate"); fillInTree(t); sortTreeAndInsertAggregateNodes(t._amount, t); otherTrees.push(t); } otherTrees.sort(TreeNode.compareUnsafeNames); // Get the length of the longest root value among the degenerate other trees, // and sort them as well. let otherDegenerates = []; let maxStringLength = 0; for (let unsafeName in aDegenerates) { let t = aDegenerates[unsafeName]; assert(t._isDegenerate, "tree is not degenerate"); let length = t.toString().length; if (length > maxStringLength) { maxStringLength = length; } otherDegenerates.push(t); } otherDegenerates.sort(TreeNode.compareUnsafeNames); // Now generate the elements, putting non-degenerate trees first. let pre = appendSectionHeader(aP, "Other Measurements"); for (let i = 0; i < otherTrees.length; i++) { let t = otherTrees[i]; appendTreeElements(pre, t, aProcess, ""); appendTextNode(pre, "\n"); // blank lines after non-degenerate trees } for (let i = 0; i < otherDegenerates.length; i++) { let t = otherDegenerates[i]; let padText = pad("", maxStringLength - t.toString().length, ' '); appendTreeElements(pre, t, aProcess, padText); } appendTextNode(aP, "\n"); // gives nice spacing when we copy and paste // Add any warnings about inaccuracies in the "explicit" tree due to platform // limitations. These must be computed after generating all the text. The // newlines give nice spacing if we copy+paste into a text buffer. if (hasExplicitTree) { appendWarningElements(warningsDiv, hasKnownHeapAllocated, aHasMozMallocUsableSize); } appendElementWithText(aP, "h3", "", "End of " + aProcess); appendLink("end", "start", kUpwardsArrow); } /** * Determines if a number has a negative sign when converted to a string. * Works even for -0. * * @param aN * The number. * @return A boolean. */ function hasNegativeSign(aN) { if (aN === 0) { // this succeeds for 0 and -0 return 1 / aN === -Infinity; // this succeeds for -0 } return aN < 0; } /** * Formats an int as a human-readable string. * * @param aN * The integer to format. * @param aExtra * An extra string to tack onto the end. * @return A human-readable string representing the int. * * Note: building an array of chars and converting that to a string with * Array.join at the end is more memory efficient than using string * concatenation. See bug 722972 for details. */ function formatInt(aN, aExtra) { let neg = false; if (hasNegativeSign(aN)) { neg = true; aN = -aN; } let s = []; while (true) { let k = aN % 1000; aN = Math.floor(aN / 1000); if (aN > 0) { if (k < 10) { s.unshift(",00", k); } else if (k < 100) { s.unshift(",0", k); } else { s.unshift(",", k); } } else { s.unshift(k); break; } } if (neg) { s.unshift("-"); } if (aExtra) { s.push(aExtra); } return s.join(""); } /** * Converts a byte count to an appropriate string representation. * * @param aBytes * The byte count. * @return The string representation. */ function formatBytes(aBytes) { let unit = gVerbose.checked ? " B" : " MB"; let s; if (gVerbose.checked) { s = formatInt(aBytes, unit); } else { let mbytes = (aBytes / (1024 * 1024)).toFixed(2); let a = String(mbytes).split("."); // If the argument to formatInt() is -0, it will print the negative sign. s = formatInt(Number(a[0])) + "." + a[1] + unit; } return s; } /** * Converts a percentage to an appropriate string representation. * * @param aPerc100x * The percentage, multiplied by 100 (see nsIMemoryReporter). * @return The string representation */ function formatPercentage(aPerc100x) { return (aPerc100x / 100).toFixed(2) + "%"; } /** * Right-justifies a string in a field of a given width, padding as necessary. * * @param aS * The string. * @param aN * The field width. * @param aC * The char used to pad. * @return The string representation. */ function pad(aS, aN, aC) { let padding = ""; let n2 = aN - aS.length; for (let i = 0; i < n2; i++) { padding += aC; } return padding + aS; } // There's a subset of the Unicode "light" box-drawing chars that is widely // implemented in terminals, and this code sticks to that subset to maximize // the chance that copying and pasting about:memory output to a terminal will // work correctly. const kHorizontal = "\u2500", kVertical = "\u2502", kUpAndRight = "\u2514", kUpAndRight_Right_Right = "\u2514\u2500\u2500", kVerticalAndRight = "\u251c", kVerticalAndRight_Right_Right = "\u251c\u2500\u2500", kVertical_Space_Space = "\u2502 "; const kNoKidsSep = " \u2500\u2500 ", kHideKidsSep = " ++ ", kShowKidsSep = " -- "; function appendMrNameSpan(aP, aDescription, aUnsafeName, aIsInvalid, aNMerged, aPresence) { let safeName = flipBackslashes(aUnsafeName); if (!aIsInvalid && !aNMerged && !aPresence) { safeName += "\n"; } let nameSpan = appendElementWithText(aP, "span", "mrName", safeName); nameSpan.title = aDescription; if (aIsInvalid) { let noteText = " [?!]"; if (!aNMerged) { noteText += "\n"; } let noteSpan = appendElementWithText(aP, "span", "mrNote", noteText); noteSpan.title = "Warning: this value is invalid and indicates a bug in one or more " + "memory reporters. "; } if (aNMerged) { let noteText = " [" + aNMerged + "]"; if (!aPresence) { noteText += "\n"; } let noteSpan = appendElementWithText(aP, "span", "mrNote", noteText); noteSpan.title = "This value is the sum of " + aNMerged + " memory reports that all have the same path."; } if (aPresence) { let c, title; switch (aPresence) { case DReport.PRESENT_IN_FIRST_ONLY: c = '-'; title = "This value was only present in the first set of memory reports."; break; case DReport.PRESENT_IN_SECOND_ONLY: c = '+'; title = "This value was only present in the second set of memory reports."; break; case DReport.ADDED_FOR_BALANCE: c = '!'; title = "One of the sets of memory reports lacked children for this " + "node's parent. This is a fake child node added to make the " + "two memory sets comparable."; break; default: assert(false, "bad presence"); break; } let noteSpan = appendElementWithText(aP, "span", "mrNote", " [" + c + "]\n"); noteSpan.title = title; } } // This is used to record the (safe) IDs of which sub-trees have been manually // expanded (marked as true) and collapsed (marked as false). It's used to // replicate the collapsed/expanded state when the page is updated. It can end // up holding IDs of nodes that no longer exist, e.g. for compartments that // have been closed. This doesn't seem like a big deal, because the number is // limited by the number of entries the user has changed from their original // state. var gShowSubtreesBySafeTreeId = {}; function assertClassListContains(e, className) { assert(e, "undefined " + className); assert(e.classList.contains(className), "classname isn't " + className); } function toggle(aEvent) { // This relies on each line being a span that contains at least four spans: // mrValue, mrPerc, mrSep, mrName, and then zero or more mrNotes. All // whitespace must be within one of these spans for this function to find the // right nodes. And the span containing the children of this line must // immediately follow. Assertions check this. // |aEvent.target| will be one of the spans. Get the outer span. let outerSpan = aEvent.target.parentNode; assertClassListContains(outerSpan, "hasKids"); // Toggle the '++'/'--' separator. let isExpansion; let sepSpan = outerSpan.childNodes[2]; assertClassListContains(sepSpan, "mrSep"); if (sepSpan.textContent === kHideKidsSep) { isExpansion = true; sepSpan.textContent = kShowKidsSep; } else if (sepSpan.textContent === kShowKidsSep) { isExpansion = false; sepSpan.textContent = kHideKidsSep; } else { assert(false, "bad sepSpan textContent"); } // Toggle visibility of the span containing this node's children. let subTreeSpan = outerSpan.nextSibling; assertClassListContains(subTreeSpan, "kids"); subTreeSpan.classList.toggle("hidden"); // Record/unrecord that this sub-tree was toggled. let safeTreeId = outerSpan.id; if (gShowSubtreesBySafeTreeId[safeTreeId] !== undefined) { delete gShowSubtreesBySafeTreeId[safeTreeId]; } else { gShowSubtreesBySafeTreeId[safeTreeId] = isExpansion; } } function expandPathToThisElement(aElement) { if (aElement.classList.contains("kids")) { // Unhide the kids. aElement.classList.remove("hidden"); expandPathToThisElement(aElement.previousSibling); // hasKids } else if (aElement.classList.contains("hasKids")) { // Change the separator to '--'. let sepSpan = aElement.childNodes[2]; assertClassListContains(sepSpan, "mrSep"); sepSpan.textContent = kShowKidsSep; expandPathToThisElement(aElement.parentNode); // kids or pre.entries } else { assertClassListContains(aElement, "entries"); } } /** * Appends the elements for the tree, including its heading. * * @param aP * The parent DOM node. * @param aRoot * The tree root. * @param aProcess * The process the tree corresponds to. * @param aPadText * A string to pad the start of each entry. */ function appendTreeElements(aP, aRoot, aProcess, aPadText) { /** * Appends the elements for a particular tree, without a heading. * * @param aP * The parent DOM node. * @param aProcess * The process the tree corresponds to. * @param aUnsafeNames * An array of the names forming the path to aT. * @param aRoot * The root of the tree this sub-tree belongs to. * @param aT * The tree. * @param aTreelineText1 * The first part of the treeline for this entry and this entry's * children. * @param aTreelineText2a * The second part of the treeline for this entry. * @param aTreelineText2b * The second part of the treeline for this entry's children. * @param aParentStringLength * The length of the formatted byte count of the top node in the tree. */ function appendTreeElements2(aP, aProcess, aUnsafeNames, aRoot, aT, aTreelineText1, aTreelineText2a, aTreelineText2b, aParentStringLength) { function appendN(aS, aC, aN) { for (let i = 0; i < aN; i++) { aS += aC; } return aS; } // The tree line. Indent more if this entry is narrower than its parent. let valueText = aT.toString(); let extraTreelineLength = Math.max(aParentStringLength - valueText.length, 0); if (extraTreelineLength > 0) { aTreelineText2a = appendN(aTreelineText2a, kHorizontal, extraTreelineLength); aTreelineText2b = appendN(aTreelineText2b, " ", extraTreelineLength); } let treelineText = aTreelineText1 + aTreelineText2a; appendElementWithText(aP, "span", "treeline", treelineText); // Detect and record invalid values. But not if gIsDiff is true, because // we expect negative values in that case. assertInput(aRoot._units === aT._units, "units within a tree are inconsistent"); let tIsInvalid = false; if (!gIsDiff && !(0 <= aT._amount && aT._amount <= aRoot._amount)) { tIsInvalid = true; let unsafePath = aUnsafeNames.join("/"); gUnsafePathsWithInvalidValuesForThisProcess.push(unsafePath); reportAssertionFailure("Invalid value (" + aT._amount + " / " + aRoot._amount + ") for " + flipBackslashes(unsafePath)); } // For non-leaf nodes, the entire sub-tree is put within a span so it can // be collapsed if the node is clicked on. let d; let sep; let showSubtrees; if (aT._kids) { // Determine if we should show the sub-tree below this entry; this // involves reinstating any previous toggling of the sub-tree. let unsafePath = aUnsafeNames.join("/"); let safeTreeId = aProcess + ":" + flipBackslashes(unsafePath); showSubtrees = !aT._hideKids; if (gShowSubtreesBySafeTreeId[safeTreeId] !== undefined) { showSubtrees = gShowSubtreesBySafeTreeId[safeTreeId]; } d = appendElement(aP, "span", "hasKids"); d.id = safeTreeId; d.onclick = toggle; sep = showSubtrees ? kShowKidsSep : kHideKidsSep; } else { assert(!aT._hideKids, "leaf node with _hideKids set") sep = kNoKidsSep; d = aP; } // The value. appendElementWithText(d, "span", "mrValue" + (tIsInvalid ? " invalid" : ""), valueText); // The percentage (omitted for single entries). let percText; if (!aT._isDegenerate) { // Treat 0 / 0 as 100%. let num = aRoot._amount === 0 ? 100 : (100 * aT._amount / aRoot._amount); let numText = num.toFixed(2); percText = numText === "100.00" ? " (100.0%)" : (0 <= num && num < 10 ? " (0" : " (") + numText + "%)"; appendElementWithText(d, "span", "mrPerc", percText); } // The separator. appendElementWithText(d, "span", "mrSep", sep); // The entry's name. appendMrNameSpan(d, aT._description, aT._unsafeName, tIsInvalid, aT._nMerged, aT._presence); // In non-verbose mode, invalid nodes can be hidden in collapsed sub-trees. // But it's good to always see them, so force this. if (!gVerbose.checked && tIsInvalid) { expandPathToThisElement(d); } // Recurse over children. if (aT._kids) { // The 'kids' class is just used for sanity checking in toggle(). d = appendElement(aP, "span", showSubtrees ? "kids" : "kids hidden"); let kidTreelineText1 = aTreelineText1 + aTreelineText2b; for (let i = 0; i < aT._kids.length; i++) { let kidTreelineText2a, kidTreelineText2b; if (i < aT._kids.length - 1) { kidTreelineText2a = kVerticalAndRight_Right_Right; kidTreelineText2b = kVertical_Space_Space; } else { kidTreelineText2a = kUpAndRight_Right_Right; kidTreelineText2b = " "; } aUnsafeNames.push(aT._kids[i]._unsafeName); appendTreeElements2(d, aProcess, aUnsafeNames, aRoot, aT._kids[i], kidTreelineText1, kidTreelineText2a, kidTreelineText2b, valueText.length); aUnsafeNames.pop(); } } } let rootStringLength = aRoot.toString().length; appendTreeElements2(aP, aProcess, [aRoot._unsafeName], aRoot, aRoot, aPadText, "", "", rootStringLength); } // --------------------------------------------------------------------------- function appendSectionHeader(aP, aText) { appendElementWithText(aP, "h2", "", aText + "\n"); return appendElement(aP, "pre", "entries"); } // --------------------------------------------------------------------------- function saveReportsToFile() { let fp = Cc["@mozilla.org/filepicker;1"].createInstance(Ci.nsIFilePicker); fp.appendFilter("Zipped JSON files", "*.json.gz"); fp.appendFilters(Ci.nsIFilePicker.filterAll); fp.filterIndex = 0; fp.addToRecentDocs = true; fp.defaultString = "memory-report.json.gz"; let fpFinish = function(file) { let dumper = Cc["@mozilla.org/memory-info-dumper;1"] .getService(Ci.nsIMemoryInfoDumper); let finishDumping = () => { updateMainAndFooter("Saved memory reports to " + file.path, HIDE_FOOTER); } dumper.dumpMemoryReportsToNamedFile(file.path, finishDumping, null, gAnonymize.checked); } let fpCallback = function(aResult) { if (aResult == Ci.nsIFilePicker.returnOK || aResult == Ci.nsIFilePicker.returnReplace) { fpFinish(fp.file); } }; try { fp.init(window, "Save Memory Reports", Ci.nsIFilePicker.modeSave); } catch (ex) { // This will fail on Android, since there is no Save as file picker there. // Just save to the default downloads dir if it does. Downloads.getSystemDownloadsDirectory().then(function(dirPath) { let file = FileUtils.File(dirPath); file.append(fp.defaultString); fpFinish(file); }); return; } fp.open(fpCallback); }