/* -*- Mode: C++; tab-width: 50; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* ***** BEGIN LICENSE BLOCK ***** * Version: MPL 1.1/GPL 2.0/LGPL 2.1 * * The contents of this file are subject to the Mozilla Public License Version * 1.1 (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License * for the specific language governing rights and limitations under the * License. * * The Original Code is mozilla.org code. * * The Initial Developer of the Original Code is * mozilla.org * Portions created by the Initial Developer are Copyright (C) 2008 * the Initial Developer. All Rights Reserved. * * Contributor(s): * Vladimir Vukicevic (original author) * Nicholas Nethercote * * Alternatively, the contents of this file may be used under the terms of * either of the GNU General Public License Version 2 or later (the "GPL"), * or the GNU Lesser General Public License Version 2.1 or later (the "LGPL"), * in which case the provisions of the GPL or the LGPL are applicable instead * of those above. If you wish to allow use of your version of this file only * under the terms of either the GPL or the LGPL, and not to allow others to * use your version of this file under the terms of the MPL, indicate your * decision by deleting the provisions above and replace them with the notice * and other provisions required by the GPL or the LGPL. If you do not delete * the provisions above, a recipient may use your version of this file under * the terms of any one of the MPL, the GPL or the LGPL. * * ***** END LICENSE BLOCK ***** */ #include "nsAtomTable.h" #include "nsAutoPtr.h" #include "nsCOMPtr.h" #include "nsServiceManagerUtils.h" #include "nsMemoryReporterManager.h" #include "nsArrayEnumerator.h" #include "nsISimpleEnumerator.h" #include "mozilla/Telemetry.h" using namespace mozilla; static PRInt64 GetExplicit() { nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); if (mgr == nsnull) return (PRInt64)-1; PRInt64 n; nsresult rv = mgr->GetExplicit(&n); NS_ENSURE_SUCCESS(rv, rv); return n; } #if defined(MOZ_MEMORY) # if defined(XP_WIN) || defined(SOLARIS) || defined(ANDROID) || defined(XP_MACOSX) # define HAVE_JEMALLOC_STATS 1 # include "jemalloc.h" # elif defined(XP_LINUX) # define HAVE_JEMALLOC_STATS 1 # include "jemalloc_types.h" // jemalloc is directly linked into firefox-bin; libxul doesn't link // with it. So if we tried to use jemalloc_stats directly here, it // wouldn't be defined. Instead, we don't include the jemalloc header // and weakly link against jemalloc_stats. extern "C" { extern void jemalloc_stats(jemalloc_stats_t* stats) NS_VISIBILITY_DEFAULT __attribute__((weak)); } # endif // XP_LINUX #endif // MOZ_MEMORY #if defined(XP_LINUX) || defined(XP_MACOSX) || defined(SOLARIS) #include #include static PRInt64 GetHardPageFaults() { struct rusage usage; int err = getrusage(RUSAGE_SELF, &usage); if (err != 0) { return PRInt64(-1); } return usage.ru_majflt; } static PRInt64 GetSoftPageFaults() { struct rusage usage; int err = getrusage(RUSAGE_SELF, &usage); if (err != 0) { return PRInt64(-1); } return usage.ru_minflt; } #endif #if defined(XP_LINUX) #include static PRInt64 GetProcSelfStatmField(int n) { // There are more than two fields, but we're only interested in the first // two. static const int MAX_FIELD = 2; size_t fields[MAX_FIELD]; NS_ASSERTION(n < MAX_FIELD, "bad field number"); FILE *f = fopen("/proc/self/statm", "r"); if (f) { int nread = fscanf(f, "%zu %zu", &fields[0], &fields[1]); fclose(f); return (PRInt64) ((nread == MAX_FIELD) ? fields[n]*getpagesize() : -1); } return (PRInt64) -1; } static PRInt64 GetVsize() { return GetProcSelfStatmField(0); } static PRInt64 GetResident() { return GetProcSelfStatmField(1); } #elif defined(SOLARIS) #include #include #include static void XMappingIter(PRInt64& Vsize, PRInt64& Resident) { Vsize = -1; Resident = -1; int mapfd = open("/proc/self/xmap", O_RDONLY); struct stat st; prxmap_t *prmapp = NULL; if (mapfd >= 0) { if (!fstat(mapfd, &st)) { int nmap = st.st_size / sizeof(prxmap_t); while (1) { // stat(2) on /proc//xmap returns an incorrect value, // prior to the release of Solaris 11. // Here is a workaround for it. nmap *= 2; prmapp = (prxmap_t*)malloc((nmap + 1) * sizeof(prxmap_t)); if (!prmapp) { // out of memory break; } int n = pread(mapfd, prmapp, (nmap + 1) * sizeof(prxmap_t), 0); if (n < 0) { break; } if (nmap >= n / sizeof (prxmap_t)) { Vsize = 0; Resident = 0; for (int i = 0; i < n / sizeof (prxmap_t); i++) { Vsize += prmapp[i].pr_size; Resident += prmapp[i].pr_rss * prmapp[i].pr_pagesize; } break; } free(prmapp); } free(prmapp); } close(mapfd); } } static PRInt64 GetVsize() { PRInt64 Vsize, Resident; XMappingIter(Vsize, Resident); return Vsize; } static PRInt64 GetResident() { PRInt64 Vsize, Resident; XMappingIter(Vsize, Resident); return Resident; } #elif defined(XP_MACOSX) #include #include static bool GetTaskBasicInfo(struct task_basic_info *ti) { mach_msg_type_number_t count = TASK_BASIC_INFO_COUNT; kern_return_t kr = task_info(mach_task_self(), TASK_BASIC_INFO, (task_info_t)ti, &count); return kr == KERN_SUCCESS; } // The VSIZE figure on Mac includes huge amounts of shared memory and is always // absurdly high, eg. 2GB+ even at start-up. But both 'top' and 'ps' report // it, so we might as well too. static PRInt64 GetVsize() { task_basic_info ti; return (PRInt64) (GetTaskBasicInfo(&ti) ? ti.virtual_size : -1); } static PRInt64 GetResident() { #ifdef HAVE_JEMALLOC_STATS // If we're using jemalloc on Mac, we need to instruct jemalloc to purge // the pages it has madvise(MADV_FREE)'d before we read our RSS. The OS // will take away MADV_FREE'd pages when there's memory pressure, so they // shouldn't count against our RSS. // // Purging these pages shouldn't take more than 10ms or so, but we want to // keep an eye on it since GetResident() is called on each Telemetry ping. { Telemetry::AutoTimer timer; jemalloc_purge_freed_pages(); } #endif task_basic_info ti; return (PRInt64) (GetTaskBasicInfo(&ti) ? ti.resident_size : -1); } #elif defined(XP_WIN) #include #include static PRInt64 GetVsize() { MEMORYSTATUSEX s; s.dwLength = sizeof(s); bool success = GlobalMemoryStatusEx(&s); if (!success) return -1; return s.ullTotalVirtual - s.ullAvailVirtual; } #if MOZ_WINSDK_TARGETVER >= MOZ_NTDDI_LONGHORN static PRInt64 GetPrivate() { PROCESS_MEMORY_COUNTERS_EX pmcex; pmcex.cb = sizeof(PROCESS_MEMORY_COUNTERS_EX); if (!GetProcessMemoryInfo(GetCurrentProcess(), (PPROCESS_MEMORY_COUNTERS) &pmcex, sizeof(pmcex))) return (PRInt64) -1; return pmcex.PrivateUsage; } NS_MEMORY_REPORTER_IMPLEMENT(Private, "private", KIND_OTHER, UNITS_BYTES, GetPrivate, "Memory that cannot be shared with other processes, including memory that " "is committed and marked MEM_PRIVATE, data that is not mapped, and " "executable pages that have been written to.") #endif static PRInt64 GetResident() { PROCESS_MEMORY_COUNTERS pmc; pmc.cb = sizeof(PROCESS_MEMORY_COUNTERS); if (!GetProcessMemoryInfo(GetCurrentProcess(), &pmc, sizeof(pmc))) return (PRInt64) -1; return pmc.WorkingSetSize; } #else static PRInt64 GetResident() { return (PRInt64) -1; } #endif #if defined(XP_LINUX) || defined(XP_MACOSX) || defined(XP_WIN) || defined(SOLARIS) NS_MEMORY_REPORTER_IMPLEMENT(Vsize, "vsize", KIND_OTHER, UNITS_BYTES, GetVsize, "Memory mapped by the process, including code and data segments, the " "heap, thread stacks, memory explicitly mapped by the process via mmap " "and similar operations, and memory shared with other processes. " "This is the vsize figure as reported by 'top' and 'ps'. This figure is of " "limited use on Mac, where processes share huge amounts of memory with one " "another. But even on other operating systems, 'resident' is a much better " "measure of the memory resources used by the process.") #endif #if defined(XP_LINUX) || defined(XP_MACOSX) || defined(SOLARIS) NS_MEMORY_REPORTER_IMPLEMENT(PageFaultsSoft, "page-faults-soft", KIND_OTHER, UNITS_COUNT_CUMULATIVE, GetSoftPageFaults, "The number of soft page faults (also known as \"minor page faults\") that " "have occurred since the process started. A soft page fault occurs when the " "process tries to access a page which is present in physical memory but is " "not mapped into the process's address space. For instance, a process might " "observe soft page faults when it loads a shared library which is already " "present in physical memory. A process may experience many thousands of soft " "page faults even when the machine has plenty of available physical memory, " "and because the OS services a soft page fault without accessing the disk, " "they impact performance much less than hard page faults.") NS_MEMORY_REPORTER_IMPLEMENT(PageFaultsHard, "page-faults-hard", KIND_OTHER, UNITS_COUNT_CUMULATIVE, GetHardPageFaults, "The number of hard page faults (also known as \"major page faults\") that " "have occurred since the process started. A hard page fault occurs when a " "process tries to access a page which is not present in physical memory. " "The operating system must access the disk in order to fulfill a hard page " "fault. When memory is plentiful, you should see very few hard page faults. " "But if the process tries to use more memory than your machine has " "available, you may see many thousands of hard page faults. Because " "accessing the disk is up to a million times slower than accessing RAM, " "the program may run very slowly when it is experiencing more than 100 or " "so hard page faults a second.") #endif NS_MEMORY_REPORTER_IMPLEMENT(Explicit, "explicit", KIND_OTHER, UNITS_BYTES, GetExplicit, "This is the same measurement as the root of the 'explicit' tree. " "However, it is measured at a different time and so gives slightly " "different results.") NS_MEMORY_REPORTER_IMPLEMENT(Resident, "resident", KIND_OTHER, UNITS_BYTES, GetResident, "Memory mapped by the process that is present in physical memory, " "also known as the resident set size (RSS). This is the best single " "figure to use when considering the memory resources used by the process, " "but it depends both on other processes being run and details of the OS " "kernel and so is best used for comparing the memory usage of a single " "process at different points in time.") /** ** memory reporter implementation for jemalloc and OSX malloc, ** to obtain info on total memory in use (that we know about, ** at least -- on OSX, there are sometimes other zones in use). **/ #if HAVE_JEMALLOC_STATS static PRInt64 GetHeapUnallocated() { jemalloc_stats_t stats; jemalloc_stats(&stats); return (PRInt64) stats.mapped - stats.allocated; } static PRInt64 GetHeapAllocated() { jemalloc_stats_t stats; jemalloc_stats(&stats); return (PRInt64) stats.allocated; } static PRInt64 GetHeapCommitted() { jemalloc_stats_t stats; jemalloc_stats(&stats); return (PRInt64) stats.committed; } static PRInt64 GetHeapCommittedFragmentation() { jemalloc_stats_t stats; jemalloc_stats(&stats); return (PRInt64) 10000 * (1 - stats.allocated / (double)stats.committed); } static PRInt64 GetHeapDirty() { jemalloc_stats_t stats; jemalloc_stats(&stats); return (PRInt64) stats.dirty; } NS_MEMORY_REPORTER_IMPLEMENT(HeapCommitted, "heap-committed", KIND_OTHER, UNITS_BYTES, GetHeapCommitted, "Memory mapped by the heap allocator that is committed, i.e. in physical " "memory or paged to disk. When heap-committed is larger than " "heap-allocated, the difference between the two values is likely due to " "external fragmentation; that is, the allocator allocated a large block of " "memory and is unable to decommit it because a small part of that block is " "currently in use.") NS_MEMORY_REPORTER_IMPLEMENT(HeapCommittedFragmentation, "heap-committed-fragmentation", KIND_OTHER, UNITS_PERCENTAGE, GetHeapCommittedFragmentation, "Fraction of committed bytes which do not correspond to an active " "allocation; i.e., 1 - (heap-allocated / heap-committed). Although the " "allocator will waste some space under any circumstances, a large value here " "may indicate that the heap is highly fragmented.") NS_MEMORY_REPORTER_IMPLEMENT(HeapDirty, "heap-dirty", KIND_OTHER, UNITS_BYTES, GetHeapDirty, "Memory which the allocator could return to the operating system, but " "hasn't. The allocator keeps this memory around as an optimization, so it " "doesn't have to ask the OS the next time it needs to fulfill a request. " "This value is typically not larger than a few megabytes.") #elif defined(XP_MACOSX) && !defined(MOZ_MEMORY) #include static PRInt64 GetHeapUnallocated() { struct mstats stats = mstats(); return (PRInt64) (stats.bytes_total - stats.bytes_used); } static PRInt64 GetHeapAllocated() { struct mstats stats = mstats(); return (PRInt64) stats.bytes_used; } static PRInt64 GetHeapZone0Committed() { #ifdef MOZ_DMD // malloc_zone_statistics() crashes when run under DMD because Valgrind // doesn't intercept it. This measurement isn't important for DMD, so // don't even try. return (PRInt64) -1; #else malloc_statistics_t stats; malloc_zone_statistics(malloc_default_zone(), &stats); return stats.size_in_use; #endif } static PRInt64 GetHeapZone0Used() { #ifdef MOZ_DMD // See comment in GetHeapZone0Committed above. return (PRInt64) -1; #else malloc_statistics_t stats; malloc_zone_statistics(malloc_default_zone(), &stats); return stats.size_allocated; #endif } NS_MEMORY_REPORTER_IMPLEMENT(HeapZone0Committed, "heap-zone0-committed", KIND_OTHER, UNITS_BYTES, GetHeapZone0Committed, "Memory mapped by the heap allocator that is committed in the default " "zone.") NS_MEMORY_REPORTER_IMPLEMENT(HeapZone0Used, "heap-zone0-used", KIND_OTHER, UNITS_BYTES, GetHeapZone0Used, "Memory mapped by the heap allocator in the default zone that is " "allocated to the application.") #else static PRInt64 GetHeapAllocated() { return (PRInt64) -1; } static PRInt64 GetHeapUnallocated() { return (PRInt64) -1; } #endif NS_MEMORY_REPORTER_IMPLEMENT(HeapUnallocated, "heap-unallocated", KIND_OTHER, UNITS_BYTES, GetHeapUnallocated, "Memory mapped by the heap allocator that is not part of an active " "allocation. Much of this memory may be uncommitted -- that is, it does not " "take up space in physical memory or in the swap file.") NS_MEMORY_REPORTER_IMPLEMENT(HeapAllocated, "heap-allocated", KIND_OTHER, UNITS_BYTES, GetHeapAllocated, "Memory mapped by the heap allocator that is currently allocated to the " "application. This may exceed the amount of memory requested by the " "application because the allocator regularly rounds up request sizes. (The " "exact amount requested is not recorded.)") NS_MEMORY_REPORTER_MALLOC_SIZEOF_FUN(AtomTableMallocSizeOf, "atom-table") static PRInt64 GetAtomTableSize() { return NS_SizeOfAtomTableIncludingThis(AtomTableMallocSizeOf); } // Why is this here? At first glance, you'd think it could be defined and // registered with nsMemoryReporterManager entirely within nsAtomTable.cpp. // However, the obvious time to register it is when the table is initialized, // and that happens before XPCOM components are initialized, which means the // NS_RegisterMemoryReporter call fails. So instead we do it here. NS_MEMORY_REPORTER_IMPLEMENT(AtomTable, "explicit/atom-table", KIND_HEAP, UNITS_BYTES, GetAtomTableSize, "Memory used by the atoms table.") /** ** nsMemoryReporterManager implementation **/ NS_IMPL_THREADSAFE_ISUPPORTS1(nsMemoryReporterManager, nsIMemoryReporterManager) NS_IMETHODIMP nsMemoryReporterManager::Init() { #if HAVE_JEMALLOC_STATS && defined(XP_LINUX) if (!jemalloc_stats) return NS_ERROR_FAILURE; #endif #define REGISTER(_x) RegisterReporter(new NS_MEMORY_REPORTER_NAME(_x)) REGISTER(HeapAllocated); REGISTER(HeapUnallocated); REGISTER(Explicit); REGISTER(Resident); #if defined(XP_LINUX) || defined(XP_MACOSX) || defined(XP_WIN) || defined(SOLARIS) REGISTER(Vsize); #endif #if defined(XP_LINUX) || defined(XP_MACOSX) || defined(SOLARIS) REGISTER(PageFaultsSoft); REGISTER(PageFaultsHard); #endif #if defined(XP_WIN) && MOZ_WINSDK_TARGETVER >= MOZ_NTDDI_LONGHORN REGISTER(Private); #endif #if defined(HAVE_JEMALLOC_STATS) REGISTER(HeapCommitted); REGISTER(HeapCommittedFragmentation); REGISTER(HeapDirty); #elif defined(XP_MACOSX) && !defined(MOZ_MEMORY) REGISTER(HeapZone0Committed); REGISTER(HeapZone0Used); #endif REGISTER(AtomTable); return NS_OK; } nsMemoryReporterManager::nsMemoryReporterManager() : mMutex("nsMemoryReporterManager::mMutex") { } nsMemoryReporterManager::~nsMemoryReporterManager() { } NS_IMETHODIMP nsMemoryReporterManager::EnumerateReporters(nsISimpleEnumerator **result) { nsresult rv; mozilla::MutexAutoLock autoLock(mMutex); rv = NS_NewArrayEnumerator(result, mReporters); return rv; } NS_IMETHODIMP nsMemoryReporterManager::EnumerateMultiReporters(nsISimpleEnumerator **result) { nsresult rv; mozilla::MutexAutoLock autoLock(mMutex); rv = NS_NewArrayEnumerator(result, mMultiReporters); return rv; } NS_IMETHODIMP nsMemoryReporterManager::RegisterReporter(nsIMemoryReporter *reporter) { mozilla::MutexAutoLock autoLock(mMutex); if (mReporters.IndexOf(reporter) != -1) return NS_ERROR_FAILURE; mReporters.AppendObject(reporter); return NS_OK; } NS_IMETHODIMP nsMemoryReporterManager::RegisterMultiReporter(nsIMemoryMultiReporter *reporter) { mozilla::MutexAutoLock autoLock(mMutex); if (mMultiReporters.IndexOf(reporter) != -1) return NS_ERROR_FAILURE; mMultiReporters.AppendObject(reporter); return NS_OK; } NS_IMETHODIMP nsMemoryReporterManager::UnregisterReporter(nsIMemoryReporter *reporter) { mozilla::MutexAutoLock autoLock(mMutex); if (!mReporters.RemoveObject(reporter)) return NS_ERROR_FAILURE; return NS_OK; } NS_IMETHODIMP nsMemoryReporterManager::UnregisterMultiReporter(nsIMemoryMultiReporter *reporter) { mozilla::MutexAutoLock autoLock(mMutex); if (!mMultiReporters.RemoveObject(reporter)) return NS_ERROR_FAILURE; return NS_OK; } NS_IMETHODIMP nsMemoryReporterManager::GetResident(PRInt64 *aResident) { *aResident = ::GetResident(); return NS_OK; } struct MemoryReport { MemoryReport(const nsACString &path, PRInt64 amount) : path(path), amount(amount) { MOZ_COUNT_CTOR(MemoryReport); } MemoryReport(const MemoryReport& rhs) : path(rhs.path), amount(rhs.amount) { MOZ_COUNT_CTOR(MemoryReport); } ~MemoryReport() { MOZ_COUNT_DTOR(MemoryReport); } const nsCString path; PRInt64 amount; }; #ifdef DEBUG // This is just a wrapper for PRInt64 that implements nsISupports, so it can be // passed to nsIMemoryMultiReporter::CollectReports. class PRInt64Wrapper : public nsISupports { public: NS_DECL_ISUPPORTS PRInt64Wrapper() : mValue(0) { } PRInt64 mValue; }; NS_IMPL_ISUPPORTS0(PRInt64Wrapper) class ExplicitNonHeapCountingCallback : public nsIMemoryMultiReporterCallback { public: NS_DECL_ISUPPORTS NS_IMETHOD Callback(const nsACString &aProcess, const nsACString &aPath, PRInt32 aKind, PRInt32 aUnits, PRInt64 aAmount, const nsACString &aDescription, nsISupports *aWrappedExplicitNonHeap) { if (aKind == nsIMemoryReporter::KIND_NONHEAP && PromiseFlatCString(aPath).Find("explicit") == 0 && aAmount != PRInt64(-1)) { PRInt64Wrapper *wrappedPRInt64 = static_cast(aWrappedExplicitNonHeap); wrappedPRInt64->mValue += aAmount; } return NS_OK; } }; NS_IMPL_ISUPPORTS1( ExplicitNonHeapCountingCallback , nsIMemoryMultiReporterCallback ) #endif NS_IMETHODIMP nsMemoryReporterManager::GetExplicit(PRInt64 *aExplicit) { NS_ENSURE_ARG_POINTER(aExplicit); *aExplicit = 0; nsresult rv; bool more; // Get "heap-allocated" and all the KIND_NONHEAP measurements from normal // (i.e. non-multi) "explicit" reporters. PRInt64 heapAllocated = PRInt64(-1); PRInt64 explicitNonHeapNormalSize = 0; nsCOMPtr e; EnumerateReporters(getter_AddRefs(e)); while (NS_SUCCEEDED(e->HasMoreElements(&more)) && more) { nsCOMPtr r; e->GetNext(getter_AddRefs(r)); PRInt32 kind; rv = r->GetKind(&kind); NS_ENSURE_SUCCESS(rv, rv); nsCString path; rv = r->GetPath(path); NS_ENSURE_SUCCESS(rv, rv); // We're only interested in NONHEAP explicit reporters and // the 'heap-allocated' reporter. if (kind == nsIMemoryReporter::KIND_NONHEAP && path.Find("explicit") == 0) { PRInt64 amount; rv = r->GetAmount(&amount); NS_ENSURE_SUCCESS(rv, rv); // Just skip any NONHEAP reporters that fail, because // "heap-allocated" is the most important one. if (amount != PRInt64(-1)) { explicitNonHeapNormalSize += amount; } } else if (path.Equals("heap-allocated")) { rv = r->GetAmount(&heapAllocated); NS_ENSURE_SUCCESS(rv, rv); // If we don't have "heap-allocated", give up, because the result would be // horribly inaccurate. if (heapAllocated == PRInt64(-1)) { *aExplicit = PRInt64(-1); return NS_OK; } } } // For each multi-reporter we could call CollectReports and filter out the // non-explicit, non-NONHEAP measurements. But that's lots of wasted work, // so we instead use GetExplicitNonHeap() which exists purely for this // purpose. // // (Actually, in debug builds we also do it the slow way and compare the // result to the result obtained from GetExplicitNonHeap(). This // guarantees the two measurement paths are equivalent. This is wise // because it's easy for memory reporters to have bugs.) PRInt64 explicitNonHeapMultiSize = 0; nsCOMPtr e2; EnumerateMultiReporters(getter_AddRefs(e2)); while (NS_SUCCEEDED(e2->HasMoreElements(&more)) && more) { nsCOMPtr r; e2->GetNext(getter_AddRefs(r)); PRInt64 n; rv = r->GetExplicitNonHeap(&n); NS_ENSURE_SUCCESS(rv, rv); explicitNonHeapMultiSize += n; } #ifdef DEBUG nsRefPtr cb = new ExplicitNonHeapCountingCallback(); nsRefPtr wrappedExplicitNonHeapMultiSize2 = new PRInt64Wrapper(); nsCOMPtr e3; EnumerateMultiReporters(getter_AddRefs(e3)); while (NS_SUCCEEDED(e3->HasMoreElements(&more)) && more) { nsCOMPtr r; e3->GetNext(getter_AddRefs(r)); r->CollectReports(cb, wrappedExplicitNonHeapMultiSize2); } PRInt64 explicitNonHeapMultiSize2 = wrappedExplicitNonHeapMultiSize2->mValue; // Check the two measurements give the same result. NS_ASSERTION(explicitNonHeapMultiSize == explicitNonHeapMultiSize2, "The two measurements of 'explicit' memory usage don't match"); #endif *aExplicit = heapAllocated + explicitNonHeapNormalSize + explicitNonHeapMultiSize; return NS_OK; } NS_IMETHODIMP nsMemoryReporterManager::GetHasMozMallocUsableSize(bool *aHas) { void *p = malloc(16); if (!p) { return NS_ERROR_OUT_OF_MEMORY; } size_t usable = moz_malloc_usable_size(p); free(p); *aHas = !!(usable > 0); return NS_OK; } NS_IMPL_ISUPPORTS1(nsMemoryReporter, nsIMemoryReporter) nsMemoryReporter::nsMemoryReporter(nsACString& process, nsACString& path, PRInt32 kind, PRInt32 units, PRInt64 amount, nsACString& desc) : mProcess(process) , mPath(path) , mKind(kind) , mUnits(units) , mAmount(amount) , mDesc(desc) { } nsMemoryReporter::~nsMemoryReporter() { } NS_IMETHODIMP nsMemoryReporter::GetProcess(nsACString &aProcess) { aProcess.Assign(mProcess); return NS_OK; } NS_IMETHODIMP nsMemoryReporter::GetPath(nsACString &aPath) { aPath.Assign(mPath); return NS_OK; } NS_IMETHODIMP nsMemoryReporter::GetKind(PRInt32 *aKind) { *aKind = mKind; return NS_OK; } NS_IMETHODIMP nsMemoryReporter::GetUnits(PRInt32 *aUnits) { *aUnits = mUnits; return NS_OK; } NS_IMETHODIMP nsMemoryReporter::GetAmount(PRInt64 *aAmount) { *aAmount = mAmount; return NS_OK; } NS_IMETHODIMP nsMemoryReporter::GetDescription(nsACString &aDescription) { aDescription.Assign(mDesc); return NS_OK; } nsresult NS_RegisterMemoryReporter (nsIMemoryReporter *reporter) { nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); if (mgr == nsnull) return NS_ERROR_FAILURE; return mgr->RegisterReporter(reporter); } nsresult NS_RegisterMemoryMultiReporter (nsIMemoryMultiReporter *reporter) { nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); if (mgr == nsnull) return NS_ERROR_FAILURE; return mgr->RegisterMultiReporter(reporter); } nsresult NS_UnregisterMemoryReporter (nsIMemoryReporter *reporter) { nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); if (mgr == nsnull) return NS_ERROR_FAILURE; return mgr->UnregisterReporter(reporter); } nsresult NS_UnregisterMemoryMultiReporter (nsIMemoryMultiReporter *reporter) { nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); if (mgr == nsnull) return NS_ERROR_FAILURE; return mgr->UnregisterMultiReporter(reporter); } namespace mozilla { #ifdef MOZ_DMD class NullMultiReporterCallback : public nsIMemoryMultiReporterCallback { public: NS_DECL_ISUPPORTS NS_IMETHOD Callback(const nsACString &aProcess, const nsACString &aPath, PRInt32 aKind, PRInt32 aUnits, PRInt64 aAmount, const nsACString &aDescription, nsISupports *aData) { // Do nothing; the reporter has already reported to DMD. return NS_OK; } }; NS_IMPL_ISUPPORTS1( NullMultiReporterCallback , nsIMemoryMultiReporterCallback ) void DMDCheckAndDump() { nsCOMPtr mgr = do_GetService("@mozilla.org/memory-reporter-manager;1"); // Do vanilla reporters. nsCOMPtr e; mgr->EnumerateReporters(getter_AddRefs(e)); bool more; while (NS_SUCCEEDED(e->HasMoreElements(&more)) && more) { nsCOMPtr r; e->GetNext(getter_AddRefs(r)); // Just getting the amount is enough for the reporter to report to DMD. PRInt64 amount; (void)r->GetAmount(&amount); } // Do multi-reporters. nsCOMPtr e2; mgr->EnumerateMultiReporters(getter_AddRefs(e2)); nsRefPtr cb = new NullMultiReporterCallback(); while (NS_SUCCEEDED(e2->HasMoreElements(&more)) && more) { nsCOMPtr r; e2->GetNext(getter_AddRefs(r)); r->CollectReports(cb, nsnull); } VALGRIND_DMD_CHECK_REPORTING; } #endif /* defined(MOZ_DMD) */ }