/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 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/. */ #include "mozilla/nsMemoryInfoDumper.h" #ifdef XP_LINUX #include "mozilla/Preferences.h" #endif #include "mozilla/unused.h" #include "mozilla/dom/ContentParent.h" #include "mozilla/dom/ContentChild.h" #include "nsIConsoleService.h" #include "nsICycleCollectorListener.h" #include "nsIMemoryReporter.h" #include "nsDirectoryServiceDefs.h" #include "nsGZFileWriter.h" #include "nsJSEnvironment.h" #include "nsPrintfCString.h" #include "nsISimpleEnumerator.h" #include "nsServiceManagerUtils.h" #include "nsIFile.h" #include #ifdef XP_WIN #include #define getpid _getpid #else #include #endif #ifdef XP_LINUX #include #include #include #endif #ifdef ANDROID #include "android/log.h" #endif #ifdef LOG #undef LOG #endif #ifdef ANDROID #define LOG(...) __android_log_print(ANDROID_LOG_INFO, "Gecko:MemoryInfoDumper", ## __VA_ARGS__) #else #define LOG(...) #endif using namespace mozilla; using namespace mozilla::dom; namespace { class DumpMemoryInfoToTempDirRunnable : public nsRunnable { public: DumpMemoryInfoToTempDirRunnable(const nsAString& aIdentifier, bool aMinimizeMemoryUsage, bool aDumpChildProcesses) : mIdentifier(aIdentifier) , mMinimizeMemoryUsage(aMinimizeMemoryUsage) , mDumpChildProcesses(aDumpChildProcesses) {} NS_IMETHOD Run() { nsCOMPtr dumper = do_GetService("@mozilla.org/memory-info-dumper;1"); dumper->DumpMemoryInfoToTempDir(mIdentifier, mMinimizeMemoryUsage, mDumpChildProcesses); return NS_OK; } private: const nsString mIdentifier; const bool mMinimizeMemoryUsage; const bool mDumpChildProcesses; }; class GCAndCCLogDumpRunnable : public nsRunnable { public: GCAndCCLogDumpRunnable(const nsAString& aIdentifier, bool aDumpAllTraces, bool aDumpChildProcesses) : mIdentifier(aIdentifier) , mDumpAllTraces(aDumpAllTraces) , mDumpChildProcesses(aDumpChildProcesses) {} NS_IMETHOD Run() { nsCOMPtr dumper = do_GetService("@mozilla.org/memory-info-dumper;1"); dumper->DumpGCAndCCLogsToFile( mIdentifier, mDumpAllTraces, mDumpChildProcesses); return NS_OK; } private: const nsString mIdentifier; const bool mDumpAllTraces; const bool mDumpChildProcesses; }; } // anonymous namespace #ifdef XP_LINUX // { namespace { /* * The following code supports dumping about:memory upon receiving a signal. * * We listen for the following signals: * * - SIGRTMIN: Dump our memory reporters (and those of our child * processes), * - SIGRTMIN + 1: Dump our memory reporters (and those of our child * processes) after minimizing memory usage, and * - SIGRTMIN + 2: Dump the GC and CC logs in this and our child processes. * * When we receive one of these signals, we write the signal number to a pipe. * The IO thread then notices that the pipe has been written to, and kicks off * the appropriate task on the main thread. * * This scheme is similar to using signalfd(), except it's portable and it * doesn't require the use of sigprocmask, which is problematic because it * masks signals received by child processes. * * In theory, we could use Chromium's MessageLoopForIO::CatchSignal() for this. * But that uses libevent, which does not handle the realtime signals (bug * 794074). */ // It turns out that at least on some systems, SIGRTMIN is not a compile-time // constant, so these have to be set at runtime. static int sDumpAboutMemorySignum; // SIGRTMIN static int sDumpAboutMemoryAfterMMUSignum; // SIGRTMIN + 1 static int sGCAndCCDumpSignum; // SIGRTMIN + 2 // This is the write-end of a pipe that we use to notice when a // dump-about-memory signal occurs. static Atomic sDumpAboutMemoryPipeWriteFd(-1); void DumpAboutMemorySignalHandler(int aSignum) { // This is a signal handler, so everything in here needs to be // async-signal-safe. Be careful! if (sDumpAboutMemoryPipeWriteFd != -1) { uint8_t signum = static_cast(aSignum); write(sDumpAboutMemoryPipeWriteFd, &signum, sizeof(signum)); } } /** * Abstract base class for something which watches an fd and takes action when * we can read from it without blocking. */ class FdWatcher : public MessageLoopForIO::Watcher , public nsIObserver { protected: MessageLoopForIO::FileDescriptorWatcher mReadWatcher; int mFd; public: FdWatcher() : mFd(-1) { MOZ_ASSERT(NS_IsMainThread()); } virtual ~FdWatcher() { // StopWatching should have run. MOZ_ASSERT(mFd == -1); } /** * Open the fd to watch. If we encounter an error, return -1. */ virtual int OpenFd() = 0; /** * Called when you can read() from the fd without blocking. Note that this * function is also called when you're at eof (read() returns 0 in this case). */ virtual void OnFileCanReadWithoutBlocking(int aFd) = 0; virtual void OnFileCanWriteWithoutBlocking(int aFd) {}; NS_DECL_THREADSAFE_ISUPPORTS /** * Initialize this object. This should be called right after the object is * constructed. (This would go in the constructor, except we interact with * XPCOM, which we can't do from a constructor because our refcount is 0 at * that point.) */ void Init() { MOZ_ASSERT(NS_IsMainThread()); nsCOMPtr os = services::GetObserverService(); os->AddObserver(this, "xpcom-shutdown", /* ownsWeak = */ false); XRE_GetIOMessageLoop()->PostTask( FROM_HERE, NewRunnableMethod(this, &FdWatcher::StartWatching)); } // Implementations may call this function multiple times if they ensure that // it's safe to call OpenFd() multiple times and they call StopWatching() // first. virtual void StartWatching() { MOZ_ASSERT(XRE_GetIOMessageLoop() == MessageLoopForIO::current()); MOZ_ASSERT(mFd == -1); mFd = OpenFd(); if (mFd == -1) { LOG("FdWatcher: OpenFd failed."); return; } MessageLoopForIO::current()->WatchFileDescriptor( mFd, /* persistent = */ true, MessageLoopForIO::WATCH_READ, &mReadWatcher, this); } // Since implementations can call StartWatching() multiple times, they can of // course call StopWatching() multiple times. virtual void StopWatching() { MOZ_ASSERT(XRE_GetIOMessageLoop() == MessageLoopForIO::current()); mReadWatcher.StopWatchingFileDescriptor(); if (mFd != -1) { close(mFd); mFd = -1; } } NS_IMETHOD Observe(nsISupports* aSubject, const char* aTopic, const PRUnichar* aData) { MOZ_ASSERT(NS_IsMainThread()); MOZ_ASSERT(!strcmp(aTopic, "xpcom-shutdown")); XRE_GetIOMessageLoop()->PostTask( FROM_HERE, NewRunnableMethod(this, &FdWatcher::StopWatching)); return NS_OK; } }; NS_IMPL_ISUPPORTS1(FdWatcher, nsIObserver); class SignalPipeWatcher : public FdWatcher { public: static void Create() { nsRefPtr sw = new SignalPipeWatcher(); sw->Init(); } virtual ~SignalPipeWatcher() { MOZ_ASSERT(sDumpAboutMemoryPipeWriteFd == -1); } virtual int OpenFd() { MOZ_ASSERT(XRE_GetIOMessageLoop() == MessageLoopForIO::current()); sDumpAboutMemorySignum = SIGRTMIN; sDumpAboutMemoryAfterMMUSignum = SIGRTMIN + 1; sGCAndCCDumpSignum = SIGRTMIN + 2; // Create a pipe. When we receive a signal in our signal handler, we'll // write the signum to the write-end of this pipe. int pipeFds[2]; if (pipe(pipeFds)) { LOG("SignalPipeWatcher failed to create pipe."); return -1; } // Close this pipe on calls to exec(). fcntl(pipeFds[0], F_SETFD, FD_CLOEXEC); fcntl(pipeFds[1], F_SETFD, FD_CLOEXEC); int readFd = pipeFds[0]; sDumpAboutMemoryPipeWriteFd = pipeFds[1]; struct sigaction action; memset(&action, 0, sizeof(action)); sigemptyset(&action.sa_mask); action.sa_handler = DumpAboutMemorySignalHandler; if (sigaction(sDumpAboutMemorySignum, &action, nullptr)) { LOG("SignalPipeWatcher failed to register about:memory " "dump signal handler."); } if (sigaction(sDumpAboutMemoryAfterMMUSignum, &action, nullptr)) { LOG("SignalPipeWatcher failed to register about:memory " "dump after MMU signal handler."); } if (sigaction(sGCAndCCDumpSignum, &action, nullptr)) { LOG("Failed to register GC+CC dump signal handler."); } return readFd; } virtual void StopWatching() { MOZ_ASSERT(XRE_GetIOMessageLoop() == MessageLoopForIO::current()); // Close sDumpAboutMemoryPipeWriteFd /after/ setting the fd to -1. // Otherwise we have the (admittedly far-fetched) race where we // // 1) close sDumpAboutMemoryPipeWriteFd // 2) open a new fd with the same number as sDumpAboutMemoryPipeWriteFd // had. // 3) receive a signal, then write to the fd. int pipeWriteFd = sDumpAboutMemoryPipeWriteFd.exchange(-1); close(pipeWriteFd); FdWatcher::StopWatching(); } virtual void OnFileCanReadWithoutBlocking(int aFd) { MOZ_ASSERT(XRE_GetIOMessageLoop() == MessageLoopForIO::current()); uint8_t signum; ssize_t numReceived = read(aFd, &signum, sizeof(signum)); if (numReceived != sizeof(signum)) { LOG("Error reading from buffer in " "SignalPipeWatcher::OnFileCanReadWithoutBlocking."); return; } if (signum == sDumpAboutMemorySignum || signum == sDumpAboutMemoryAfterMMUSignum) { // Dump our memory reports (but run this on the main thread!). bool doMMUFirst = signum == sDumpAboutMemoryAfterMMUSignum; nsRefPtr runnable = new DumpMemoryInfoToTempDirRunnable(/* identifier = */ EmptyString(), doMMUFirst, /* dumpChildProcesses = */ true); NS_DispatchToMainThread(runnable); } else if (signum == sGCAndCCDumpSignum) { // Dump GC and CC logs (from the main thread). nsRefPtr runnable = new GCAndCCLogDumpRunnable( /* identifier = */ EmptyString(), /* allTraces = */ true, /* dumpChildProcesses = */ true); NS_DispatchToMainThread(runnable); } else { LOG("SignalPipeWatcher got unexpected signum."); } } }; class FifoWatcher : public FdWatcher { public: static void MaybeCreate() { MOZ_ASSERT(NS_IsMainThread()); if (XRE_GetProcessType() != GeckoProcessType_Default) { // We want this to be main-process only, since two processes can't listen // to the same fifo. return; } if (!Preferences::GetBool("memory_info_dumper.watch_fifo.enabled", false)) { LOG("Fifo watcher disabled via pref."); return; } // The FifoWatcher is held alive by the observer service. nsRefPtr fw = new FifoWatcher(); fw->Init(); } virtual int OpenFd() { // If the memory_info_dumper.directory pref is specified, put the fifo // there. Otherwise, put it into the system's tmp directory. nsCOMPtr file; nsAutoCString dirPath; nsresult rv = Preferences::GetCString( "memory_info_dumper.watch_fifo.directory", &dirPath); if (NS_SUCCEEDED(rv)) { rv = XRE_GetFileFromPath(dirPath.get(), getter_AddRefs(file)); if (NS_FAILED(rv)) { LOG("FifoWatcher failed to open file \"%s\"", dirPath.get()); return -1; } } else { rv = NS_GetSpecialDirectory(NS_OS_TEMP_DIR, getter_AddRefs(file)); NS_ENSURE_SUCCESS(rv, -1); } rv = file->AppendNative(NS_LITERAL_CSTRING("debug_info_trigger")); NS_ENSURE_SUCCESS(rv, -1); nsAutoCString path; rv = file->GetNativePath(path); NS_ENSURE_SUCCESS(rv, -1); // unlink might fail because the file doesn't exist, or for other reasons. // But we don't care it fails; any problems will be detected later, when we // try to mkfifo or open the file. if (unlink(path.get())) { LOG("FifoWatcher::OpenFifo unlink failed; errno=%d. " "Continuing despite error.", errno); } if (mkfifo(path.get(), 0766)) { LOG("FifoWatcher::OpenFifo mkfifo failed; errno=%d", errno); return -1; } #ifdef ANDROID // Android runs with a umask, so we need to chmod our fifo to make it // world-writable. chmod(path.get(), 0666); #endif int fd; do { // The fifo will block until someone else has written to it. In // particular, open() will block until someone else has opened it for // writing! We want open() to succeed and read() to block, so we open // with NONBLOCK and then fcntl that away. fd = open(path.get(), O_RDONLY | O_NONBLOCK); } while (fd == -1 && errno == EINTR); if (fd == -1) { LOG("FifoWatcher::OpenFifo open failed; errno=%d", errno); return -1; } // Make fd blocking now that we've opened it. if (fcntl(fd, F_SETFL, 0)) { close(fd); return -1; } return fd; } virtual void OnFileCanReadWithoutBlocking(int aFd) { MOZ_ASSERT(XRE_GetIOMessageLoop() == MessageLoopForIO::current()); char buf[1024]; int nread; do { // sizeof(buf) - 1 to leave space for the null-terminator. nread = read(aFd, buf, sizeof(buf)); } while(nread == -1 && errno == EINTR); if (nread == -1) { // We want to avoid getting into a situation where // OnFileCanReadWithoutBlocking is called in an infinite loop, so when // something goes wrong, stop watching the fifo altogether. LOG("FifoWatcher hit an error (%d) and is quitting.", errno); StopWatching(); return; } if (nread == 0) { // If we get EOF, that means that the other side closed the fifo. We need // to close and re-open the fifo; if we don't, // OnFileCanWriteWithoutBlocking will be called in an infinite loop. LOG("FifoWatcher closing and re-opening fifo."); StopWatching(); StartWatching(); return; } nsAutoCString inputStr; inputStr.Append(buf, nread); // Trimming whitespace is important because if you do // |echo "foo" >> debug_info_trigger|, // it'll actually write "foo\n" to the fifo. inputStr.Trim("\b\t\r\n"); bool doMemoryReport = inputStr == NS_LITERAL_CSTRING("memory report"); bool doMMUMemoryReport = inputStr == NS_LITERAL_CSTRING("minimize memory report"); bool doAllTracesGCCCDump = inputStr == NS_LITERAL_CSTRING("gc log"); bool doSmallGCCCDump = inputStr == NS_LITERAL_CSTRING("abbreviated gc log"); if (doMemoryReport || doMMUMemoryReport) { LOG("FifoWatcher dispatching memory report runnable."); nsRefPtr runnable = new DumpMemoryInfoToTempDirRunnable(/* identifier = */ EmptyString(), doMMUMemoryReport, /* dumpChildProcesses = */ true); NS_DispatchToMainThread(runnable); } else if (doAllTracesGCCCDump || doSmallGCCCDump) { LOG("FifoWatcher dispatching GC/CC log runnable."); nsRefPtr runnable = new GCAndCCLogDumpRunnable( /* identifier = */ EmptyString(), doAllTracesGCCCDump, /* dumpChildProcesses = */ true); NS_DispatchToMainThread(runnable); } else { LOG("Got unexpected value from fifo; ignoring it."); } } }; } // anonymous namespace #endif // XP_LINUX } NS_IMPL_ISUPPORTS1(nsMemoryInfoDumper, nsIMemoryInfoDumper) nsMemoryInfoDumper::nsMemoryInfoDumper() { } nsMemoryInfoDumper::~nsMemoryInfoDumper() { } /* static */ void nsMemoryInfoDumper::Initialize() { #ifdef XP_LINUX SignalPipeWatcher::Create(); FifoWatcher::MaybeCreate(); #endif } static void EnsureNonEmptyIdentifier(nsAString& aIdentifier) { if (!aIdentifier.IsEmpty()) { return; } // If the identifier is empty, set it to the number of whole seconds since the // epoch. This identifier will appear in the files that this process // generates and also the files generated by this process's children, allowing // us to identify which files are from the same memory report request. aIdentifier.AppendInt(static_cast(PR_Now()) / 1000000); } NS_IMETHODIMP nsMemoryInfoDumper::DumpGCAndCCLogsToFile( const nsAString& aIdentifier, bool aDumpAllTraces, bool aDumpChildProcesses) { nsString identifier(aIdentifier); EnsureNonEmptyIdentifier(identifier); if (aDumpChildProcesses) { nsTArray children; ContentParent::GetAll(children); for (uint32_t i = 0; i < children.Length(); i++) { unused << children[i]->SendDumpGCAndCCLogsToFile( identifier, aDumpAllTraces, aDumpChildProcesses); } } nsCOMPtr logger = do_CreateInstance("@mozilla.org/cycle-collector-logger;1"); logger->SetFilenameIdentifier(identifier); if (aDumpAllTraces) { nsCOMPtr allTracesLogger; logger->AllTraces(getter_AddRefs(allTracesLogger)); logger = allTracesLogger; } nsJSContext::CycleCollectNow(logger); return NS_OK; } namespace mozilla { #define DUMP(o, s) \ do { \ nsresult rv = (o)->Write(s); \ NS_ENSURE_SUCCESS(rv, rv); \ } while (0) static nsresult DumpReport(nsIGZFileWriter *aWriter, bool aIsFirst, const nsACString &aProcess, const nsACString &aPath, int32_t aKind, int32_t aUnits, int64_t aAmount, const nsACString &aDescription) { DUMP(aWriter, aIsFirst ? "[" : ","); nsAutoCString process; if (aProcess.IsEmpty()) { // If the process is empty, the report originated with the process doing // the dumping. In that case, generate the process identifier, which is of // the form "$PROCESS_NAME (pid $PID)", or just "(pid $PID)" if we don't // have a process name. If we're the main process, we let $PROCESS_NAME be // "Main Process". if (XRE_GetProcessType() == GeckoProcessType_Default) { // We're the main process. process.AssignLiteral("Main Process"); } else if (ContentChild *cc = ContentChild::GetSingleton()) { // Try to get the process name from ContentChild. cc->GetProcessName(process); } ContentChild::AppendProcessId(process); } else { // Otherwise, the report originated with another process and already has a // process name. Just use that. process = aProcess; } DUMP(aWriter, "\n {\"process\": \""); DUMP(aWriter, process); DUMP(aWriter, "\", \"path\": \""); nsCString path(aPath); path.ReplaceSubstring("\\", "\\\\"); /* --> \\ */ path.ReplaceSubstring("\"", "\\\""); // " --> \" DUMP(aWriter, path); DUMP(aWriter, "\", \"kind\": "); DUMP(aWriter, nsPrintfCString("%d", aKind)); DUMP(aWriter, ", \"units\": "); DUMP(aWriter, nsPrintfCString("%d", aUnits)); DUMP(aWriter, ", \"amount\": "); DUMP(aWriter, nsPrintfCString("%lld", aAmount)); nsCString description(aDescription); description.ReplaceSubstring("\\", "\\\\"); /* --> \\ */ description.ReplaceSubstring("\"", "\\\""); // " --> \" description.ReplaceSubstring("\n", "\\n"); // --> \n DUMP(aWriter, ", \"description\": \""); DUMP(aWriter, description); DUMP(aWriter, "\"}"); return NS_OK; } class DumpReportCallback MOZ_FINAL : public nsIHandleReportCallback { public: NS_DECL_ISUPPORTS DumpReportCallback() : mIsFirst(true) {} NS_IMETHOD Callback(const nsACString &aProcess, const nsACString &aPath, int32_t aKind, int32_t aUnits, int64_t aAmount, const nsACString &aDescription, nsISupports *aData) { nsCOMPtr writer = do_QueryInterface(aData); NS_ENSURE_TRUE(writer, NS_ERROR_FAILURE); nsresult rv = DumpReport(writer, mIsFirst, aProcess, aPath, aKind, aUnits, aAmount, aDescription); mIsFirst = false; return rv; } private: bool mIsFirst; }; NS_IMPL_ISUPPORTS1(DumpReportCallback, nsIHandleReportCallback) } // namespace mozilla static void MakeFilename(const char *aPrefix, const nsAString &aIdentifier, const char *aSuffix, nsACString &aResult) { aResult = nsPrintfCString("%s-%s-%d.%s", aPrefix, NS_ConvertUTF16toUTF8(aIdentifier).get(), getpid(), aSuffix); } /* static */ nsresult nsMemoryInfoDumper::OpenTempFile(const nsACString &aFilename, nsIFile* *aFile) { #ifdef ANDROID // For Android, first try the downloads directory which is world-readable // rather than the temp directory which is not. if (!*aFile) { char *env = PR_GetEnv("DOWNLOADS_DIRECTORY"); if (env) { NS_NewNativeLocalFile(nsCString(env), /* followLinks = */ true, aFile); } } #endif nsresult rv; if (!*aFile) { rv = NS_GetSpecialDirectory(NS_OS_TEMP_DIR, aFile); NS_ENSURE_SUCCESS(rv, rv); } #ifdef ANDROID // /data/local/tmp is a true tmp directory; anyone can create a file there, // but only the user which created the file can remove it. We want non-root // users to be able to remove these files, so we write them into a // subdirectory of the temp directory and chmod 777 that directory. rv = (*aFile)->AppendNative(NS_LITERAL_CSTRING("memory-reports")); NS_ENSURE_SUCCESS(rv, rv); // It's OK if this fails; that probably just means that the directory already // exists. (*aFile)->Create(nsIFile::DIRECTORY_TYPE, 0777); nsAutoCString dirPath; rv = (*aFile)->GetNativePath(dirPath); NS_ENSURE_SUCCESS(rv, rv); while (chmod(dirPath.get(), 0777) == -1 && errno == EINTR) {} #endif nsCOMPtr file(*aFile); rv = file->AppendNative(aFilename); NS_ENSURE_SUCCESS(rv, rv); rv = file->CreateUnique(nsIFile::NORMAL_FILE_TYPE, 0666); NS_ENSURE_SUCCESS(rv, rv); #ifdef ANDROID // Make this file world-read/writable; the permissions passed to the // CreateUnique call above are not sufficient on Android, which runs with a // umask. nsAutoCString path; rv = file->GetNativePath(path); NS_ENSURE_SUCCESS(rv, rv); while (chmod(path.get(), 0666) == -1 && errno == EINTR) {} #endif return NS_OK; } #ifdef MOZ_DMD struct DMDWriteState { static const size_t kBufSize = 4096; char mBuf[kBufSize]; nsRefPtr mGZWriter; DMDWriteState(nsGZFileWriter *aGZWriter) : mGZWriter(aGZWriter) {} }; static void DMDWrite(void* aState, const char* aFmt, va_list ap) { DMDWriteState *state = (DMDWriteState*)aState; vsnprintf(state->mBuf, state->kBufSize, aFmt, ap); unused << state->mGZWriter->Write(state->mBuf); } #endif static nsresult DumpHeader(nsIGZFileWriter* aWriter) { // Increment this number if the format changes. // // This is the first write to the file, and it causes |aWriter| to allocate // over 200 KiB of memory. // DUMP(aWriter, "{\n \"version\": 1,\n"); DUMP(aWriter, " \"hasMozMallocUsableSize\": "); nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); NS_ENSURE_STATE(mgr); DUMP(aWriter, mgr->GetHasMozMallocUsableSize() ? "true" : "false"); DUMP(aWriter, ",\n"); DUMP(aWriter, " \"reports\": "); return NS_OK; } static nsresult DumpFooter(nsIGZFileWriter* aWriter) { DUMP(aWriter, "\n ]\n}\n"); return NS_OK; } static nsresult DumpProcessMemoryReportsToGZFileWriter(nsIGZFileWriter* aWriter) { nsresult rv = DumpHeader(aWriter); NS_ENSURE_SUCCESS(rv, rv); // Process reporters. bool more; nsCOMPtr e; nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); mgr->EnumerateReporters(getter_AddRefs(e)); nsRefPtr dumpReport = new DumpReportCallback(); while (NS_SUCCEEDED(e->HasMoreElements(&more)) && more) { nsCOMPtr r; e->GetNext(getter_AddRefs(r)); r->CollectReports(dumpReport, aWriter); } return DumpFooter(aWriter); } nsresult DumpProcessMemoryInfoToTempDir(const nsAString& aIdentifier) { MOZ_ASSERT(!aIdentifier.IsEmpty()); #ifdef MOZ_DMD // Clear DMD's reportedness state before running the memory reporters, to // avoid spurious twice-reported warnings. dmd::ClearReports(); #endif // Open a new file named something like // // incomplete-memory-report--.json.gz // // in NS_OS_TEMP_DIR for writing. When we're finished writing the report, // we'll rename this file and get rid of the "incomplete-" prefix. // // We do this because we don't want scripts which poll the filesystem // looking for memory report dumps to grab a file before we're finished // writing to it. // Note that |mrFilename| is missing the "incomplete-" prefix; we'll tack // that on in a moment. nsCString mrFilename; MakeFilename("memory-report", aIdentifier, "json.gz", mrFilename); nsCOMPtr mrTmpFile; nsresult rv; rv = nsMemoryInfoDumper::OpenTempFile(NS_LITERAL_CSTRING("incomplete-") + mrFilename, getter_AddRefs(mrTmpFile)); NS_ENSURE_SUCCESS(rv, rv); nsRefPtr mrWriter = new nsGZFileWriter(); rv = mrWriter->Init(mrTmpFile); NS_ENSURE_SUCCESS(rv, rv); // Dump the memory reports to the file. DumpProcessMemoryReportsToGZFileWriter(mrWriter); #ifdef MOZ_DMD // Create a filename like dmd--.txt.gz, which will be used // if DMD is enabled. nsCString dmdFilename; MakeFilename("dmd", aIdentifier, "txt.gz", dmdFilename); // Open a new DMD file named |dmdFilename| in NS_OS_TEMP_DIR for writing, // and dump DMD output to it. This must occur after the memory reporters // have been run (above), but before the memory-reports file has been // renamed (so scripts can detect the DMD file, if present). nsCOMPtr dmdFile; rv = nsMemoryInfoDumper::OpenTempFile(dmdFilename, getter_AddRefs(dmdFile)); NS_ENSURE_SUCCESS(rv, rv); nsRefPtr dmdWriter = new nsGZFileWriter(); rv = dmdWriter->Init(dmdFile); NS_ENSURE_SUCCESS(rv, rv); // Dump DMD output to the file. DMDWriteState state(dmdWriter); dmd::Writer w(DMDWrite, &state); dmd::Dump(w); rv = dmdWriter->Finish(); NS_ENSURE_SUCCESS(rv, rv); #endif // MOZ_DMD // The call to Finish() deallocates the memory allocated by mrWriter's first // DUMP() call (within DumpProcessMemoryReportsToGZFileWriter()). Because // that memory was live while the memory reporters ran and thus measured by // them -- by "heap-allocated" if nothing else -- we want DMD to see it as // well. So we deliberately don't call Finish() until after DMD finishes. rv = mrWriter->Finish(); NS_ENSURE_SUCCESS(rv, rv); // Rename the memory reports file, now that we're done writing all the files. // Its final name is "memory-report<-identifier>-.json.gz". nsCOMPtr mrFinalFile; rv = NS_GetSpecialDirectory(NS_OS_TEMP_DIR, getter_AddRefs(mrFinalFile)); NS_ENSURE_SUCCESS(rv, rv); #ifdef ANDROID rv = mrFinalFile->AppendNative(NS_LITERAL_CSTRING("memory-reports")); NS_ENSURE_SUCCESS(rv, rv); #endif rv = mrFinalFile->AppendNative(mrFilename); NS_ENSURE_SUCCESS(rv, rv); rv = mrFinalFile->CreateUnique(nsIFile::NORMAL_FILE_TYPE, 0600); NS_ENSURE_SUCCESS(rv, rv); nsAutoString mrActualFinalFilename; rv = mrFinalFile->GetLeafName(mrActualFinalFilename); NS_ENSURE_SUCCESS(rv, rv); rv = mrTmpFile->MoveTo(/* directory */ nullptr, mrActualFinalFilename); NS_ENSURE_SUCCESS(rv, rv); // Write a message to the console. nsCOMPtr cs = do_GetService(NS_CONSOLESERVICE_CONTRACTID, &rv); NS_ENSURE_SUCCESS(rv, rv); nsString path; mrTmpFile->GetPath(path); NS_ENSURE_SUCCESS(rv, rv); nsString msg = NS_LITERAL_STRING( "nsIMemoryInfoDumper dumped reports to "); msg.Append(path); return cs->LogStringMessage(msg.get()); } NS_IMETHODIMP nsMemoryInfoDumper::DumpMemoryInfoToTempDir(const nsAString& aIdentifier, bool aMinimizeMemoryUsage, bool aDumpChildProcesses) { nsString identifier(aIdentifier); EnsureNonEmptyIdentifier(identifier); // Kick off memory report dumps in our child processes, if applicable. We // do this before doing our own report because writing a report may be I/O // bound, in which case we want to busy the CPU with other reports while we // work on our own. if (aDumpChildProcesses) { nsTArray children; ContentParent::GetAll(children); for (uint32_t i = 0; i < children.Length(); i++) { unused << children[i]->SendDumpMemoryInfoToTempDir( identifier, aMinimizeMemoryUsage, aDumpChildProcesses); } } if (aMinimizeMemoryUsage) { // Minimize memory usage, then run DumpMemoryInfoToTempDir again. nsRefPtr callback = new DumpMemoryInfoToTempDirRunnable(identifier, /* minimizeMemoryUsage = */ false, /* dumpChildProcesses = */ false); nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); NS_ENSURE_TRUE(mgr, NS_ERROR_FAILURE); nsCOMPtr runnable; mgr->MinimizeMemoryUsage(callback, getter_AddRefs(runnable)); return NS_OK; } return DumpProcessMemoryInfoToTempDir(identifier); } // This dumps the JSON footer and closes the file, and then calls the given // nsIFinishDumpingCallback. class FinishReportingCallback MOZ_FINAL : public nsIFinishReportingCallback { public: NS_DECL_ISUPPORTS FinishReportingCallback(nsIFinishDumpingCallback* aFinishDumping, nsISupports* aFinishDumpingData) : mFinishDumping(aFinishDumping) , mFinishDumpingData(aFinishDumpingData) {} NS_IMETHOD Callback(nsISupports* aData) { nsCOMPtr writer = do_QueryInterface(aData); NS_ENSURE_TRUE(writer, NS_ERROR_FAILURE); nsresult rv = DumpFooter(writer); NS_ENSURE_SUCCESS(rv, rv); rv = writer->Finish(); NS_ENSURE_SUCCESS(rv, rv); return mFinishDumping->Callback(mFinishDumpingData); } private: nsCOMPtr mFinishDumping; nsCOMPtr mFinishDumpingData; }; NS_IMPL_ISUPPORTS1(FinishReportingCallback, nsIFinishReportingCallback) NS_IMETHODIMP nsMemoryInfoDumper::DumpMemoryReportsToNamedFile( const nsAString& aFilename, nsIFinishDumpingCallback* aFinishDumping, nsISupports* aFinishDumpingData) { MOZ_ASSERT(!aFilename.IsEmpty()); // Create the file. nsCOMPtr mrFile; nsresult rv = NS_NewLocalFile(aFilename, false, getter_AddRefs(mrFile)); NS_ENSURE_SUCCESS(rv, rv); mrFile->InitWithPath(aFilename); NS_ENSURE_SUCCESS(rv, rv); bool exists; rv = mrFile->Exists(&exists); NS_ENSURE_SUCCESS(rv, rv); if (!exists) { rv = mrFile->Create(nsIFile::NORMAL_FILE_TYPE, 0644); NS_ENSURE_SUCCESS(rv, rv); } // Write the memory reports to the file. nsRefPtr mrWriter = new nsGZFileWriter(); rv = mrWriter->Init(mrFile); NS_ENSURE_SUCCESS(rv, rv); rv = DumpHeader(mrWriter); NS_ENSURE_SUCCESS(rv, rv); // Process reports and finish up. nsRefPtr dumpReport = new DumpReportCallback(); nsRefPtr finishReporting = new FinishReportingCallback(aFinishDumping, aFinishDumpingData); nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); return mgr->GetReports(dumpReport, mrWriter, finishReporting, mrWriter); } #undef DUMP