/* -*- 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 "MemorySnapshot.h" #include "ipc/ChildInternal.h" #include "mozilla/Maybe.h" #include "DirtyMemoryHandler.h" #include "InfallibleVector.h" #include "ProcessRecordReplay.h" #include "ProcessRewind.h" #include "SpinLock.h" #include "SplayTree.h" #include "Thread.h" #include #include #include // Define to enable the countdown debugging thread. See StartCountdown(). //#define WANT_COUNTDOWN_THREAD 1 namespace mozilla { namespace recordreplay { /////////////////////////////////////////////////////////////////////////////// // Memory Snapshots Overview. // // Checkpoints are periodically saved, storing in memory enough information // for the process to restore the contents of all tracked memory as it // rewinds to earlier checkpoitns. There are two components to a saved // checkpoint: // // - Stack contents for each thread are completely saved on disk at each saved // checkpoint. This is handled by ThreadSnapshot.cpp // // - Heap and static memory contents (tracked memory) are saved in memory as // the contents of pages modified before either the the next saved checkpoint // or the current execution point (if this is the last saved checkpoint). // This is handled here. // // Heap memory is only tracked when allocated with TrackedMemoryKind. // // Snapshots of heap/static memory is modeled on the copy-on-write semantics // used by fork. Instead of actually forking, we use write-protected memory and // a fault handler to perform the copy-on-write, which both gives more control // of the snapshot process and allows snapshots to be taken on platforms // without fork (i.e. Windows). The following example shows how snapshots are // generated: // // #1 Save Checkpoint A. The initial snapshot tabulates all allocated tracked // memory in the process, and write-protects all of it. // // #2 Write pages P0 and P1. Writing to the pages trips the fault handler. The // handler creates copies of the initial contents of P0 and P1 (P0a and P1a) // and unprotects the pages. // // #3 Save Checkpoint B. P0a and P1a, along with any other pages modified // between A and B, become associated with checkpoint A. All modified pages // are reprotected. // // #4 Write pages P1 and P2. Again, writing to the pages trips the fault // handler and copies P1b and P2b are created and the pages are unprotected. // // #5 Save Checkpoint C. P1b and P2b become associated with snapshot B, and the // modified pages are reprotected. // // If we were to then rewind from C to A, we would read and restore P1b/P2b, // followed by P0a/P1a. All data associated with checkpoints A and later is // discarded (we can only rewind; we cannot jump forward in time). /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// // Snapshot Threads Overview. // // After step #3 above, the main thread has created a diff snapshot with the // copies of the original contents of pages modified between two saved // checkpoints. These page copies are initially all in memory. It is the // responsibility of the snapshot threads to do the following: // // 1. When rewinding to the last saved checkpoint, snapshot threads are used to // restore the original contents of pages using their in-memory copies. // // There are a fixed number of snapshot threads that are spawned when the // first checkpoint is saved. Threads are each responsible for distinct sets of // heap memory pages (see AddDirtyPageToWorklist), avoiding synchronization // issues between different snapshot threads. /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// // Memory Snapshot Structures /////////////////////////////////////////////////////////////////////////////// // A region of allocated memory which should be tracked by MemoryInfo. struct AllocatedMemoryRegion { uint8_t* mBase; size_t mSize; bool mExecutable; AllocatedMemoryRegion() : mBase(nullptr), mSize(0), mExecutable(false) {} AllocatedMemoryRegion(uint8_t* aBase, size_t aSize, bool aExecutable) : mBase(aBase), mSize(aSize), mExecutable(aExecutable) {} // For sorting regions by base address. struct AddressSort { typedef void* Lookup; static void* getLookup(const AllocatedMemoryRegion& aRegion) { return aRegion.mBase; } static ssize_t compare(void* aAddress, const AllocatedMemoryRegion& aRegion) { return (uint8_t*)aAddress - aRegion.mBase; } }; // For sorting regions by size, from largest to smallest. struct SizeReverseSort { typedef size_t Lookup; static size_t getLookup(const AllocatedMemoryRegion& aRegion) { return aRegion.mSize; } static ssize_t compare(size_t aSize, const AllocatedMemoryRegion& aRegion) { return aRegion.mSize - aSize; } }; }; // Information about a page which was modified between two saved checkpoints. struct DirtyPage { // Base address of the page. uint8_t* mBase; // Copy of the page at the first checkpoint. Written by the dirty memory // handler via HandleDirtyMemoryFault if this is in the active page set, // otherwise accessed by snapshot threads. uint8_t* mOriginal; bool mExecutable; DirtyPage(uint8_t* aBase, uint8_t* aOriginal, bool aExecutable) : mBase(aBase), mOriginal(aOriginal), mExecutable(aExecutable) {} struct AddressSort { typedef uint8_t* Lookup; static uint8_t* getLookup(const DirtyPage& aPage) { return aPage.mBase; } static ssize_t compare(uint8_t* aBase, const DirtyPage& aPage) { return aBase - aPage.mBase; } }; }; // A set of dirty pages that can be searched quickly. typedef SplayTree, 4> SortedDirtyPageSet; // A set of dirty pages associated with some checkpoint. struct DirtyPageSet { // Checkpoint associated with this set. size_t mCheckpoint; // All dirty pages in the set. Pages may be added or destroyed by the main // thread when all other threads are idle, by the dirty memory handler when // it is active and this is the active page set, and by the snapshot thread // which owns this set. InfallibleVector> mPages; explicit DirtyPageSet(size_t aCheckpoint) : mCheckpoint(aCheckpoint) {} }; // Worklist used by each snapshot thread. struct SnapshotThreadWorklist { // Index into gMemoryInfo->mSnapshotWorklists of the thread. size_t mThreadIndex; // Record/replay ID of the thread. size_t mThreadId; // Sets of pages in the thread's worklist. Each set is for a different diff, // with the oldest checkpoints first. InfallibleVector> mSets; }; // Structure used to coordinate activity between the main thread and all // snapshot threads. The workflow with this structure is as follows: // // 1. The main thread calls ActivateBegin(), marking the condition as active // and notifying each snapshot thread. The main thread blocks in this call. // // 2. Each snapshot thread, maybe after waking up, checks the condition, does // any processing it needs to (knowing the main thread is blocked) and // then calls WaitUntilNoLongerActive(), blocking in the call. // // 3. Once all snapshot threads are blocked in WaitUntilNoLongerActive(), the // main thread is unblocked from ActivateBegin(). It can then do whatever // processing it needs to (knowing all snapshot threads are blocked) and // then calls ActivateEnd(), blocking in the call. // // 4. Snapshot threads are now unblocked from WaitUntilNoLongerActive(). The // main thread does not unblock from ActivateEnd() until all snapshot // threads have left WaitUntilNoLongerActive(). // // The intent with this class is to ensure that the main thread knows exactly // when the snapshot threads are operating and that there is no potential for // races between them. class SnapshotThreadCondition { Atomic mActive; Atomic mCount; public: void ActivateBegin(); void ActivateEnd(); bool IsActive(); void WaitUntilNoLongerActive(); }; static const size_t NumSnapshotThreads = 8; // A set of free regions in the process. There are two of these, for the // free regions in tracked and untracked memory. class FreeRegionSet { // Kind of memory being managed. This also describes the memory used by the // set itself. MemoryKind mKind; // Lock protecting contents of the structure. SpinLock mLock; // To avoid reentrancy issues when growing the set, a chunk of pages for // the splay tree is preallocated for use the next time the tree needs to // expand its size. static const size_t ChunkPages = 4; void* mNextChunk; // Ensure there is a chunk available for the splay tree. void MaybeRefillNextChunk(AutoSpinLock& aLockHeld); // Get the next chunk from the free region set for this memory kind. void* TakeNextChunk(); struct MyAllocPolicy { FreeRegionSet& mSet; template void free_(T* aPtr, size_t aSize) { MOZ_CRASH(); } template T* pod_malloc(size_t aNumElems) { MOZ_RELEASE_ASSERT(sizeof(T) * aNumElems <= ChunkPages * PageSize); return (T*)mSet.TakeNextChunk(); } explicit MyAllocPolicy(FreeRegionSet& aSet) : mSet(aSet) {} }; // All memory in gMemoryInfo->mTrackedRegions that is not in use at the // current point in execution. typedef SplayTree Tree; Tree mRegions; void InsertLockHeld(void* aAddress, size_t aSize, AutoSpinLock& aLockHeld); void* ExtractLockHeld(size_t aSize, AutoSpinLock& aLockHeld); public: explicit FreeRegionSet(MemoryKind aKind) : mKind(aKind), mRegions(MyAllocPolicy(*this)) {} // Get the single region set for a given memory kind. static FreeRegionSet& Get(MemoryKind aKind); // Add a free region to the set. void Insert(void* aAddress, size_t aSize); // Remove a free region of the specified size. If aAddress is specified then // this address will be prioritized, but a different pointer may be returned. // The resulting memory will be zeroed. void* Extract(void* aAddress, size_t aSize); // Return whether a memory range intersects this set at all. bool Intersects(void* aAddress, size_t aSize); }; // Information about the current memory state. The contents of this structure // are in untracked memory. struct MemoryInfo { // Whether new dirty pages or allocated regions are allowed. bool mMemoryChangesAllowed; // Untracked memory regions allocated before the first checkpoint. This is // only accessed on the main thread, and is not a vector because of reentrancy // issues. static const size_t MaxInitialUntrackedRegions = 512; AllocatedMemoryRegion mInitialUntrackedRegions[MaxInitialUntrackedRegions]; SpinLock mInitialUntrackedRegionsLock; // All tracked memory in the process. This may be updated by any thread while // holding mTrackedRegionsLock. SplayTree, 4> mTrackedRegions; InfallibleVector> mTrackedRegionsByAllocationOrder; SpinLock mTrackedRegionsLock; // Pages from |trackedRegions| modified since the last saved checkpoint. // Accessed by any thread (usually the dirty memory handler) when memory // changes are allowed, and by the main thread when memory changes are not // allowed. SortedDirtyPageSet mActiveDirty; SpinLock mActiveDirtyLock; // All untracked memory which is available for new allocations. FreeRegionSet mFreeUntrackedRegions; // Worklists for each snapshot thread. SnapshotThreadWorklist mSnapshotWorklists[NumSnapshotThreads]; // Whether snapshot threads should update memory to that when the last saved // diff was started. SnapshotThreadCondition mSnapshotThreadsShouldRestore; // Whether snapshot threads should idle. SnapshotThreadCondition mSnapshotThreadsShouldIdle; // Counter used by the countdown thread. Atomic mCountdown; // Information for timers. double mStartTime; uint32_t mTimeHits[(size_t)TimerKind::Count]; double mTimeTotals[(size_t)TimerKind::Count]; // Information for memory allocation. Atomic mMemoryBalance[(size_t)MemoryKind::Count]; // Recent dirty memory faults. void* mDirtyMemoryFaults[50]; MemoryInfo() : mMemoryChangesAllowed(true), mFreeUntrackedRegions(MemoryKind::FreeRegions), mStartTime(CurrentTime()) { // The singleton MemoryInfo is allocated with zeroed memory, so other // fields do not need explicit initialization. } }; static MemoryInfo* gMemoryInfo = nullptr; void SetMemoryChangesAllowed(bool aAllowed) { MOZ_RELEASE_ASSERT(gMemoryInfo->mMemoryChangesAllowed == !aAllowed); gMemoryInfo->mMemoryChangesAllowed = aAllowed; } static void EnsureMemoryChangesAllowed() { while (!gMemoryInfo->mMemoryChangesAllowed) { ThreadYield(); } } void StartCountdown(size_t aCount) { gMemoryInfo->mCountdown = aCount; } AutoCountdown::AutoCountdown(size_t aCount) { StartCountdown(aCount); } AutoCountdown::~AutoCountdown() { StartCountdown(0); } #ifdef WANT_COUNTDOWN_THREAD static void CountdownThreadMain(void*) { while (true) { if (gMemoryInfo->mCountdown && --gMemoryInfo->mCountdown == 0) { // When debugging hangs in the child process, we can break here in lldb // to inspect what the process is doing. child::ReportFatalError(Nothing(), "CountdownThread activated"); } ThreadYield(); } } #endif // WANT_COUNTDOWN_THREAD /////////////////////////////////////////////////////////////////////////////// // Profiling /////////////////////////////////////////////////////////////////////////////// AutoTimer::AutoTimer(TimerKind aKind) : mKind(aKind), mStart(CurrentTime()) {} AutoTimer::~AutoTimer() { if (gMemoryInfo) { gMemoryInfo->mTimeHits[(size_t)mKind]++; gMemoryInfo->mTimeTotals[(size_t)mKind] += CurrentTime() - mStart; } } static const char* gTimerKindNames[] = { #define DefineTimerKindName(aKind) #aKind, ForEachTimerKind(DefineTimerKindName) #undef DefineTimerKindName }; void DumpTimers() { if (!gMemoryInfo) { return; } Print("Times %.2fs\n", (CurrentTime() - gMemoryInfo->mStartTime) / 1000000.0); for (size_t i = 0; i < (size_t)TimerKind::Count; i++) { uint32_t hits = gMemoryInfo->mTimeHits[i]; double time = gMemoryInfo->mTimeTotals[i]; Print("%s: %d hits, %.2fs\n", gTimerKindNames[i], (int)hits, time / 1000000.0); } } /////////////////////////////////////////////////////////////////////////////// // Snapshot Thread Conditions /////////////////////////////////////////////////////////////////////////////// void SnapshotThreadCondition::ActivateBegin() { MOZ_RELEASE_ASSERT(Thread::CurrentIsMainThread()); MOZ_RELEASE_ASSERT(!mActive); mActive = true; for (size_t i = 0; i < NumSnapshotThreads; i++) { Thread::Notify(gMemoryInfo->mSnapshotWorklists[i].mThreadId); } while (mCount != NumSnapshotThreads) { Thread::WaitNoIdle(); } } void SnapshotThreadCondition::ActivateEnd() { MOZ_RELEASE_ASSERT(Thread::CurrentIsMainThread()); MOZ_RELEASE_ASSERT(mActive); mActive = false; for (size_t i = 0; i < NumSnapshotThreads; i++) { Thread::Notify(gMemoryInfo->mSnapshotWorklists[i].mThreadId); } while (mCount) { Thread::WaitNoIdle(); } } bool SnapshotThreadCondition::IsActive() { MOZ_RELEASE_ASSERT(!Thread::CurrentIsMainThread()); return mActive; } void SnapshotThreadCondition::WaitUntilNoLongerActive() { MOZ_RELEASE_ASSERT(!Thread::CurrentIsMainThread()); MOZ_RELEASE_ASSERT(mActive); if (NumSnapshotThreads == ++mCount) { Thread::Notify(MainThreadId); } while (mActive) { Thread::WaitNoIdle(); } if (0 == --mCount) { Thread::Notify(MainThreadId); } } /////////////////////////////////////////////////////////////////////////////// // Snapshot Page Allocation /////////////////////////////////////////////////////////////////////////////// // Get a page in untracked memory that can be used as a copy of a tracked page. static uint8_t* AllocatePageCopy() { return (uint8_t*)AllocateMemory(PageSize, MemoryKind::PageCopy); } // Free a page allocated by AllocatePageCopy. static void FreePageCopy(uint8_t* aPage) { DeallocateMemory(aPage, PageSize, MemoryKind::PageCopy); } /////////////////////////////////////////////////////////////////////////////// // Page Fault Handling /////////////////////////////////////////////////////////////////////////////// void MemoryMove(void* aDst, const void* aSrc, size_t aSize) { MOZ_RELEASE_ASSERT((size_t)aDst % sizeof(uint32_t) == 0); MOZ_RELEASE_ASSERT((size_t)aSrc % sizeof(uint32_t) == 0); MOZ_RELEASE_ASSERT(aSize % sizeof(uint32_t) == 0); MOZ_RELEASE_ASSERT((size_t)aDst <= (size_t)aSrc || (size_t)aDst >= (size_t)aSrc + aSize); uint32_t* ndst = (uint32_t*)aDst; const uint32_t* nsrc = (const uint32_t*)aSrc; for (size_t i = 0; i < aSize / sizeof(uint32_t); i++) { ndst[i] = nsrc[i]; } } void MemoryZero(void* aDst, size_t aSize) { MOZ_RELEASE_ASSERT((size_t)aDst % sizeof(uint32_t) == 0); MOZ_RELEASE_ASSERT(aSize % sizeof(uint32_t) == 0); // Use volatile here to avoid annoying clang optimizations. volatile uint32_t* ndst = (uint32_t*)aDst; for (size_t i = 0; i < aSize / sizeof(uint32_t); i++) { ndst[i] = 0; } } // Return whether an address is in a tracked region. This excludes memory that // is in an active new region and is not write protected. static bool IsTrackedAddress(void* aAddress, bool* aExecutable) { AutoSpinLock lock(gMemoryInfo->mTrackedRegionsLock); Maybe region = gMemoryInfo->mTrackedRegions.lookupClosestLessOrEqual(aAddress); if (region.isSome() && MemoryContains(region.ref().mBase, region.ref().mSize, aAddress)) { if (aExecutable) { *aExecutable = region.ref().mExecutable; } return true; } return false; } bool HandleDirtyMemoryFault(uint8_t* aAddress) { EnsureMemoryChangesAllowed(); bool different = false; for (size_t i = ArrayLength(gMemoryInfo->mDirtyMemoryFaults) - 1; i; i--) { gMemoryInfo->mDirtyMemoryFaults[i] = gMemoryInfo->mDirtyMemoryFaults[i - 1]; if (gMemoryInfo->mDirtyMemoryFaults[i] != aAddress) { different = true; } } gMemoryInfo->mDirtyMemoryFaults[0] = aAddress; if (!different) { Print("WARNING: Repeated accesses to the same dirty address %p\n", aAddress); } // Round down to the base of the page. aAddress = PageBase(aAddress); AutoSpinLock lock(gMemoryInfo->mActiveDirtyLock); // Check to see if this is already an active dirty page. Once a page has been // marked as dirty it will be accessible until the next checkpoint is saved, // but it's possible for multiple threads to access the same protected memory // before we have a chance to unprotect it, in which case we'll end up here // multiple times for the page. if (gMemoryInfo->mActiveDirty.maybeLookup(aAddress)) { return true; } // Crash if this address is not in a tracked region. bool executable; if (!IsTrackedAddress(aAddress, &executable)) { return false; } // Copy the page's original contents into the active dirty set, and unprotect // it so that execution can proceed. uint8_t* original = AllocatePageCopy(); MemoryMove(original, aAddress, PageSize); gMemoryInfo->mActiveDirty.insert(aAddress, DirtyPage(aAddress, original, executable)); DirectUnprotectMemory(aAddress, PageSize, executable); return true; } bool MemoryRangeIsTracked(void* aAddress, size_t aSize) { for (uint8_t* ptr = PageBase(aAddress); ptr < (uint8_t*)aAddress + aSize; ptr += PageSize) { if (!IsTrackedAddress(ptr, nullptr)) { return false; } } return true; } void UnrecoverableSnapshotFailure() { if (gMemoryInfo) { AutoSpinLock lock(gMemoryInfo->mTrackedRegionsLock); DirectUnprotectMemory(PageBase(&errno), PageSize, false); for (auto region : gMemoryInfo->mTrackedRegionsByAllocationOrder) { DirectUnprotectMemory(region.mBase, region.mSize, region.mExecutable, /* aIgnoreFailures = */ true); } } } /////////////////////////////////////////////////////////////////////////////// // Initial Memory Region Processing /////////////////////////////////////////////////////////////////////////////// void AddInitialUntrackedMemoryRegion(uint8_t* aBase, size_t aSize) { MOZ_RELEASE_ASSERT(!HasSavedAnyCheckpoint()); if (gInitializationFailureMessage) { return; } static void* gSkippedRegion; if (!gSkippedRegion) { // We are allocating gMemoryInfo itself, and will directly call this // function again shortly. gSkippedRegion = aBase; return; } MOZ_RELEASE_ASSERT(gSkippedRegion == gMemoryInfo); AutoSpinLock lock(gMemoryInfo->mInitialUntrackedRegionsLock); for (AllocatedMemoryRegion& region : gMemoryInfo->mInitialUntrackedRegions) { if (!region.mBase) { region.mBase = aBase; region.mSize = aSize; return; } } // If we end up here then MaxInitialUntrackedRegions should be larger. MOZ_CRASH(); } static void RemoveInitialUntrackedRegion(uint8_t* aBase, size_t aSize) { MOZ_RELEASE_ASSERT(!HasSavedAnyCheckpoint()); AutoSpinLock lock(gMemoryInfo->mInitialUntrackedRegionsLock); for (AllocatedMemoryRegion& region : gMemoryInfo->mInitialUntrackedRegions) { if (region.mBase == aBase) { MOZ_RELEASE_ASSERT(region.mSize == aSize); region.mBase = nullptr; region.mSize = 0; return; } } MOZ_CRASH(); } // Get information about the mapped region containing *aAddress, or the next // mapped region afterwards if aAddress is not mapped. aAddress is updated to // the start of that region, and aSize, aProtection, and aMaxProtection are // updated with the size and protection status of the region. Returns false if // there are no more mapped regions after *aAddress. static bool QueryRegion(uint8_t** aAddress, size_t* aSize, int* aProtection = nullptr, int* aMaxProtection = nullptr) { mach_vm_address_t addr = (mach_vm_address_t)*aAddress; mach_vm_size_t nbytes; vm_region_basic_info_64 info; mach_msg_type_number_t info_count = sizeof(vm_region_basic_info_64); mach_port_t some_port; kern_return_t rv = mach_vm_region(mach_task_self(), &addr, &nbytes, VM_REGION_BASIC_INFO, (vm_region_info_t)&info, &info_count, &some_port); if (rv == KERN_INVALID_ADDRESS) { return false; } MOZ_RELEASE_ASSERT(rv == KERN_SUCCESS); *aAddress = (uint8_t*)addr; *aSize = nbytes; if (aProtection) { *aProtection = info.protection; } if (aMaxProtection) { *aMaxProtection = info.max_protection; } return true; } static void MarkThreadStacksAsUntracked() { AutoPassThroughThreadEvents pt; // Thread stacks are excluded from the tracked regions. for (size_t i = MainThreadId; i <= MaxThreadId; i++) { Thread* thread = Thread::GetById(i); if (!thread->StackBase()) { continue; } AddInitialUntrackedMemoryRegion(thread->StackBase(), thread->StackSize()); // Look for a mapped region with no access permissions immediately after // the thread stack's allocated region, and include this in the untracked // memory if found. This is done to avoid confusing breakpad, which will // scan the allocated memory in this process and will not correctly // determine stack boundaries if we track these trailing regions and end up // marking them as readable. // Find the mapped region containing the end of the thread's stack. uint8_t* base = thread->StackBase() + thread->StackSize() - 1; size_t size; if (!QueryRegion(&base, &size)) { MOZ_CRASH("Could not find memory region information for thread stack"); } // Sanity check the region size. Note that we don't mark this entire region // as untracked, since it may contain TLS data which should be tracked. MOZ_RELEASE_ASSERT(base + size >= thread->StackBase() + thread->StackSize()); uint8_t* trailing = base + size; size_t trailingSize; int protection; if (QueryRegion(&trailing, &trailingSize, &protection)) { if (trailing == base + size && protection == 0) { AddInitialUntrackedMemoryRegion(trailing, trailingSize); } } } } // Given an address region [*aAddress, *aAddress + *aSize], return true if // there is any intersection with an excluded region // [aExclude, aExclude + aExcludeSize], set *aSize to contain the subregion // starting at aAddress which which is not excluded, and *aRemaining and // *aRemainingSize to any additional subregion which is not excluded. static bool MaybeExtractMemoryRegion(uint8_t* aAddress, size_t* aSize, uint8_t** aRemaining, size_t* aRemainingSize, uint8_t* aExclude, size_t aExcludeSize) { uint8_t* addrLimit = aAddress + *aSize; // Expand the excluded region out to the containing page boundaries. MOZ_RELEASE_ASSERT((size_t)aExclude % PageSize == 0); aExcludeSize = RoundupSizeToPageBoundary(aExcludeSize); uint8_t* excludeLimit = aExclude + aExcludeSize; if (excludeLimit <= aAddress || addrLimit <= aExclude) { // No intersection. return false; } *aSize = std::max(aExclude - aAddress, 0); if (aRemaining) { *aRemaining = excludeLimit; *aRemainingSize = std::max(addrLimit - *aRemaining, 0); } return true; } // Set *aSize to describe the number of bytes starting at aAddress that should // be considered tracked memory. *aRemaining and *aRemainingSize are set to any // remaining portion of the initial region after the first excluded portion // that is found. static void ExtractTrackedInitialMemoryRegion(uint8_t* aAddress, size_t* aSize, uint8_t** aRemaining, size_t* aRemainingSize) { // Look for the earliest untracked region which intersects the given region. const AllocatedMemoryRegion* earliestIntersect = nullptr; for (const AllocatedMemoryRegion& region : gMemoryInfo->mInitialUntrackedRegions) { size_t size = *aSize; if (MaybeExtractMemoryRegion(aAddress, &size, nullptr, nullptr, region.mBase, region.mSize)) { // There was an intersection. if (!earliestIntersect || region.mBase < earliestIntersect->mBase) { earliestIntersect = ®ion; } } } if (earliestIntersect) { if (!MaybeExtractMemoryRegion(aAddress, aSize, aRemaining, aRemainingSize, earliestIntersect->mBase, earliestIntersect->mSize)) { MOZ_CRASH(); } } else { // If there is no intersection then the entire region is tracked. *aRemaining = aAddress + *aSize; *aRemainingSize = 0; } } static void AddTrackedRegion(uint8_t* aAddress, size_t aSize, bool aExecutable) { if (aSize) { AutoSpinLock lock(gMemoryInfo->mTrackedRegionsLock); gMemoryInfo->mTrackedRegions.insert( aAddress, AllocatedMemoryRegion(aAddress, aSize, aExecutable)); gMemoryInfo->mTrackedRegionsByAllocationOrder.emplaceBack(aAddress, aSize, aExecutable); } } // Add any tracked subregions of [aAddress, aAddress + aSize]. void AddInitialTrackedMemoryRegions(uint8_t* aAddress, size_t aSize, bool aExecutable) { while (aSize) { uint8_t* remaining; size_t remainingSize; ExtractTrackedInitialMemoryRegion(aAddress, &aSize, &remaining, &remainingSize); AddTrackedRegion(aAddress, aSize, aExecutable); aAddress = remaining; aSize = remainingSize; } } static void UpdateNumTrackedRegionsForSnapshot(); // Fill in the set of tracked memory regions that are currently mapped within // this process. static void ProcessAllInitialMemoryRegions() { MOZ_ASSERT(!AreThreadEventsPassedThrough()); { AutoPassThroughThreadEvents pt; for (uint8_t* addr = nullptr;;) { size_t size; int maxProtection; if (!QueryRegion(&addr, &size, nullptr, &maxProtection)) { break; } // Consider all memory regions that can possibly be written to, even if // they aren't currently writable. if (maxProtection & VM_PROT_WRITE) { MOZ_RELEASE_ASSERT(maxProtection & VM_PROT_READ); AddInitialTrackedMemoryRegions(addr, size, maxProtection & VM_PROT_EXECUTE); } addr += size; } } UpdateNumTrackedRegionsForSnapshot(); // Write protect all tracked memory. AutoDisallowMemoryChanges disallow; for (const AllocatedMemoryRegion& region : gMemoryInfo->mTrackedRegionsByAllocationOrder) { DirectWriteProtectMemory(region.mBase, region.mSize, region.mExecutable); } } /////////////////////////////////////////////////////////////////////////////// // Free Region Management /////////////////////////////////////////////////////////////////////////////// // All memory in gMemoryInfo->mTrackedRegions that is not in use at the current // point in execution. static FreeRegionSet gFreeRegions(MemoryKind::Tracked); // The size of gMemoryInfo->mTrackedRegionsByAllocationOrder we expect to see // at the point of the last saved checkpoint. static size_t gNumTrackedRegions; static void UpdateNumTrackedRegionsForSnapshot() { MOZ_ASSERT(Thread::CurrentIsMainThread()); gNumTrackedRegions = gMemoryInfo->mTrackedRegionsByAllocationOrder.length(); } void FixupFreeRegionsAfterRewind() { // All memory that has been allocated since the associated checkpoint was // reached is now free, and may be reused for new allocations. size_t newTrackedRegions = gMemoryInfo->mTrackedRegionsByAllocationOrder.length(); for (size_t i = gNumTrackedRegions; i < newTrackedRegions; i++) { const AllocatedMemoryRegion& region = gMemoryInfo->mTrackedRegionsByAllocationOrder[i]; gFreeRegions.Insert(region.mBase, region.mSize); } gNumTrackedRegions = newTrackedRegions; } /* static */ FreeRegionSet& FreeRegionSet::Get(MemoryKind aKind) { return (aKind == MemoryKind::Tracked) ? gFreeRegions : gMemoryInfo->mFreeUntrackedRegions; } void* FreeRegionSet::TakeNextChunk() { MOZ_RELEASE_ASSERT(mNextChunk); void* res = mNextChunk; mNextChunk = nullptr; return res; } void FreeRegionSet::InsertLockHeld(void* aAddress, size_t aSize, AutoSpinLock& aLockHeld) { mRegions.insert(aSize, AllocatedMemoryRegion((uint8_t*)aAddress, aSize, true)); } void FreeRegionSet::MaybeRefillNextChunk(AutoSpinLock& aLockHeld) { if (mNextChunk) { return; } // Look for a free region we can take the next chunk from. size_t size = ChunkPages * PageSize; gMemoryInfo->mMemoryBalance[(size_t)mKind] += size; mNextChunk = ExtractLockHeld(size, aLockHeld); if (!mNextChunk) { // Allocate memory from the system. mNextChunk = DirectAllocateMemory(nullptr, size); RegisterAllocatedMemory(mNextChunk, size, mKind); } } void FreeRegionSet::Insert(void* aAddress, size_t aSize) { MOZ_RELEASE_ASSERT(aAddress && aAddress == PageBase(aAddress)); MOZ_RELEASE_ASSERT(aSize && aSize == RoundupSizeToPageBoundary(aSize)); AutoSpinLock lock(mLock); MaybeRefillNextChunk(lock); InsertLockHeld(aAddress, aSize, lock); } void* FreeRegionSet::ExtractLockHeld(size_t aSize, AutoSpinLock& aLockHeld) { Maybe best = mRegions.lookupClosestLessOrEqual(aSize, /* aRemove = */ true); if (best.isSome()) { MOZ_RELEASE_ASSERT(best.ref().mSize >= aSize); uint8_t* res = best.ref().mBase; if (best.ref().mSize > aSize) { InsertLockHeld(res + aSize, best.ref().mSize - aSize, aLockHeld); } MemoryZero(res, aSize); return res; } return nullptr; } void* FreeRegionSet::Extract(void* aAddress, size_t aSize) { MOZ_RELEASE_ASSERT(aAddress == PageBase(aAddress)); MOZ_RELEASE_ASSERT(aSize && aSize == RoundupSizeToPageBoundary(aSize)); AutoSpinLock lock(mLock); if (aAddress) { MaybeRefillNextChunk(lock); // We were given a point at which to try to place the allocation. Look for // a free region which contains [aAddress, aAddress + aSize] entirely. for (typename Tree::Iter iter = mRegions.begin(); !iter.done(); ++iter) { uint8_t* regionBase = iter.ref().mBase; uint8_t* regionExtent = regionBase + iter.ref().mSize; uint8_t* addrBase = (uint8_t*)aAddress; uint8_t* addrExtent = addrBase + aSize; if (regionBase <= addrBase && regionExtent >= addrExtent) { iter.removeEntry(); if (regionBase < addrBase) { InsertLockHeld(regionBase, addrBase - regionBase, lock); } if (regionExtent > addrExtent) { InsertLockHeld(addrExtent, regionExtent - addrExtent, lock); } MemoryZero(aAddress, aSize); return aAddress; } } // Fall through and look for a free region at another address. } // No address hint, look for the smallest free region which is larger than // the desired allocation size. return ExtractLockHeld(aSize, lock); } bool FreeRegionSet::Intersects(void* aAddress, size_t aSize) { AutoSpinLock lock(mLock); for (typename Tree::Iter iter = mRegions.begin(); !iter.done(); ++iter) { if (MemoryIntersects(iter.ref().mBase, iter.ref().mSize, aAddress, aSize)) { return true; } } return false; } /////////////////////////////////////////////////////////////////////////////// // Memory Management /////////////////////////////////////////////////////////////////////////////// void RegisterAllocatedMemory(void* aBaseAddress, size_t aSize, MemoryKind aKind) { MOZ_RELEASE_ASSERT(aBaseAddress == PageBase(aBaseAddress)); MOZ_RELEASE_ASSERT(aSize == RoundupSizeToPageBoundary(aSize)); uint8_t* aAddress = reinterpret_cast(aBaseAddress); if (aKind != MemoryKind::Tracked) { if (!HasSavedAnyCheckpoint()) { AddInitialUntrackedMemoryRegion(aAddress, aSize); } } else if (HasSavedAnyCheckpoint()) { EnsureMemoryChangesAllowed(); DirectWriteProtectMemory(aAddress, aSize, true); AddTrackedRegion(aAddress, aSize, true); } } void CheckFixedMemory(void* aAddress, size_t aSize) { MOZ_RELEASE_ASSERT(aAddress == PageBase(aAddress)); MOZ_RELEASE_ASSERT(aSize == RoundupSizeToPageBoundary(aSize)); if (!HasSavedAnyCheckpoint()) { return; } { // The memory should already be tracked. Check each page in the allocation // because there might be tracked regions adjacent to one another, neither // of which entirely contains this memory. AutoSpinLock lock(gMemoryInfo->mTrackedRegionsLock); for (size_t offset = 0; offset < aSize; offset += PageSize) { uint8_t* page = (uint8_t*)aAddress + offset; Maybe region = gMemoryInfo->mTrackedRegions.lookupClosestLessOrEqual(page); if (!region.isSome() || !MemoryContains(region.ref().mBase, region.ref().mSize, page, PageSize)) { MOZ_CRASH("Fixed memory is not tracked!"); } } } // The memory should not be free. if (gFreeRegions.Intersects(aAddress, aSize)) { MOZ_CRASH("Fixed memory is currently free!"); } } void RestoreWritableFixedMemory(void* aAddress, size_t aSize) { MOZ_RELEASE_ASSERT(aAddress == PageBase(aAddress)); MOZ_RELEASE_ASSERT(aSize == RoundupSizeToPageBoundary(aSize)); if (!HasSavedAnyCheckpoint()) { return; } AutoSpinLock lock(gMemoryInfo->mActiveDirtyLock); for (size_t offset = 0; offset < aSize; offset += PageSize) { uint8_t* page = (uint8_t*)aAddress + offset; if (gMemoryInfo->mActiveDirty.maybeLookup(page)) { DirectUnprotectMemory(page, PageSize, true); } } } void* AllocateMemoryTryAddress(void* aAddress, size_t aSize, MemoryKind aKind) { MOZ_RELEASE_ASSERT(aAddress == PageBase(aAddress)); aSize = RoundupSizeToPageBoundary(aSize); if (gMemoryInfo) { gMemoryInfo->mMemoryBalance[(size_t)aKind] += aSize; } if (HasSavedAnyCheckpoint()) { if (void* res = FreeRegionSet::Get(aKind).Extract(aAddress, aSize)) { return res; } } void* res = DirectAllocateMemory(aAddress, aSize); RegisterAllocatedMemory(res, aSize, aKind); return res; } void* AllocateMemory(size_t aSize, MemoryKind aKind) { if (!IsReplaying()) { return DirectAllocateMemory(nullptr, aSize); } return AllocateMemoryTryAddress(nullptr, aSize, aKind); } void DeallocateMemory(void* aAddress, size_t aSize, MemoryKind aKind) { // Round the supplied region to the containing page boundaries. aSize += (uint8_t*)aAddress - PageBase(aAddress); aAddress = PageBase(aAddress); aSize = RoundupSizeToPageBoundary(aSize); if (!aAddress || !aSize) { return; } if (gMemoryInfo) { gMemoryInfo->mMemoryBalance[(size_t)aKind] -= aSize; } // Memory is returned to the system before saving the first checkpoint. if (!HasSavedAnyCheckpoint()) { if (IsReplaying() && aKind != MemoryKind::Tracked) { RemoveInitialUntrackedRegion((uint8_t*)aAddress, aSize); } DirectDeallocateMemory(aAddress, aSize); return; } if (aKind == MemoryKind::Tracked) { // For simplicity, all free regions must be executable, so ignore // deallocated memory in regions that are not executable. bool executable; if (!IsTrackedAddress(aAddress, &executable) || !executable) { return; } } // Mark this region as free, but do not unmap it. It will become usable for // later allocations, but will not need to be remapped if we end up // rewinding to a point where this memory was in use. FreeRegionSet::Get(aKind).Insert(aAddress, aSize); } /////////////////////////////////////////////////////////////////////////////// // Snapshot Threads /////////////////////////////////////////////////////////////////////////////// // While on a snapshot thread, restore the contents of all pages belonging to // this thread which were modified since the last recorded diff snapshot. static void SnapshotThreadRestoreLastDiffSnapshot( SnapshotThreadWorklist* aWorklist) { size_t checkpoint = GetLastSavedCheckpoint(); DirtyPageSet& set = aWorklist->mSets.back(); MOZ_RELEASE_ASSERT(set.mCheckpoint == checkpoint); // Copy the original contents of all pages. for (size_t index = 0; index < set.mPages.length(); index++) { const DirtyPage& page = set.mPages[index]; MOZ_RELEASE_ASSERT(page.mOriginal); DirectUnprotectMemory(page.mBase, PageSize, page.mExecutable); MemoryMove(page.mBase, page.mOriginal, PageSize); DirectWriteProtectMemory(page.mBase, PageSize, page.mExecutable); FreePageCopy(page.mOriginal); } // Remove the set from the worklist, if necessary. if (!aWorklist->mSets.empty()) { MOZ_RELEASE_ASSERT(&set == &aWorklist->mSets.back()); aWorklist->mSets.popBack(); } } // Start routine for a snapshot thread. void SnapshotThreadMain(void* aArgument) { size_t threadIndex = (size_t)aArgument; SnapshotThreadWorklist* worklist = &gMemoryInfo->mSnapshotWorklists[threadIndex]; worklist->mThreadIndex = threadIndex; while (true) { // If the main thread is waiting for us to restore the most recent diff, // then do so and notify the main thread we finished. if (gMemoryInfo->mSnapshotThreadsShouldRestore.IsActive()) { SnapshotThreadRestoreLastDiffSnapshot(worklist); gMemoryInfo->mSnapshotThreadsShouldRestore.WaitUntilNoLongerActive(); } // Idle if the main thread wants us to. if (gMemoryInfo->mSnapshotThreadsShouldIdle.IsActive()) { gMemoryInfo->mSnapshotThreadsShouldIdle.WaitUntilNoLongerActive(); } // Idle until notified by the main thread. Thread::WaitNoIdle(); } } // An alternative to memcmp that can be called from any place. static bool MemoryEquals(void* aDst, void* aSrc, size_t aSize) { MOZ_ASSERT((size_t)aDst % sizeof(size_t) == 0); MOZ_ASSERT((size_t)aSrc % sizeof(size_t) == 0); MOZ_ASSERT(aSize % sizeof(size_t) == 0); size_t* ndst = (size_t*)aDst; size_t* nsrc = (size_t*)aSrc; for (size_t i = 0; i < aSize / sizeof(size_t); i++) { if (ndst[i] != nsrc[i]) { return false; } } return true; } // Add a page to the last set in some snapshot thread's worklist. This is // called on the main thread while the snapshot thread is idle. static void AddDirtyPageToWorklist(uint8_t* aAddress, uint8_t* aOriginal, bool aExecutable) { // Distribute pages to snapshot threads using the base address of a page. // This guarantees that the same page will be consistently assigned to the // same thread as different snapshots are taken. MOZ_ASSERT((size_t)aAddress % PageSize == 0); if (MemoryEquals(aAddress, aOriginal, PageSize)) { FreePageCopy(aOriginal); } else { size_t pageIndex = ((size_t)aAddress / PageSize) % NumSnapshotThreads; SnapshotThreadWorklist* worklist = &gMemoryInfo->mSnapshotWorklists[pageIndex]; MOZ_RELEASE_ASSERT(!worklist->mSets.empty()); DirtyPageSet& set = worklist->mSets.back(); MOZ_RELEASE_ASSERT(set.mCheckpoint == GetLastSavedCheckpoint()); set.mPages.emplaceBack(aAddress, aOriginal, aExecutable); } } /////////////////////////////////////////////////////////////////////////////// // Snapshot Interface /////////////////////////////////////////////////////////////////////////////// void InitializeMemorySnapshots() { MOZ_RELEASE_ASSERT(gMemoryInfo == nullptr); void* memory = AllocateMemory(sizeof(MemoryInfo), MemoryKind::Generic); gMemoryInfo = new (memory) MemoryInfo(); // Mark gMemoryInfo as untracked. See AddInitialUntrackedMemoryRegion. AddInitialUntrackedMemoryRegion(reinterpret_cast(memory), sizeof(MemoryInfo)); } void InitializeCountdownThread() { #ifdef WANT_COUNTDOWN_THREAD Thread::SpawnNonRecordedThread(CountdownThreadMain, nullptr); #endif } void TakeFirstMemorySnapshot() { MOZ_RELEASE_ASSERT(Thread::CurrentIsMainThread()); MOZ_RELEASE_ASSERT(gMemoryInfo->mTrackedRegions.empty()); // Spawn all snapshot threads. { AutoPassThroughThreadEvents pt; for (size_t i = 0; i < NumSnapshotThreads; i++) { Thread* thread = Thread::SpawnNonRecordedThread(SnapshotThreadMain, (void*)i); gMemoryInfo->mSnapshotWorklists[i].mThreadId = thread->Id(); } } // All threads should have been created by now. MarkThreadStacksAsUntracked(); // Fill in the tracked regions for the process. ProcessAllInitialMemoryRegions(); } void TakeDiffMemorySnapshot() { MOZ_RELEASE_ASSERT(Thread::CurrentIsMainThread()); UpdateNumTrackedRegionsForSnapshot(); AutoDisallowMemoryChanges disallow; // Stop all snapshot threads while we modify their worklists. gMemoryInfo->mSnapshotThreadsShouldIdle.ActivateBegin(); // Add a DirtyPageSet to each snapshot thread's worklist for this snapshot. for (size_t i = 0; i < NumSnapshotThreads; i++) { SnapshotThreadWorklist* worklist = &gMemoryInfo->mSnapshotWorklists[i]; worklist->mSets.emplaceBack(GetLastSavedCheckpoint()); } // Distribute remaining active dirty pages to the snapshot thread worklists. for (SortedDirtyPageSet::Iter iter = gMemoryInfo->mActiveDirty.begin(); !iter.done(); ++iter) { AddDirtyPageToWorklist(iter.ref().mBase, iter.ref().mOriginal, iter.ref().mExecutable); DirectWriteProtectMemory(iter.ref().mBase, PageSize, iter.ref().mExecutable); } gMemoryInfo->mActiveDirty.clear(); // Allow snapshot threads to resume execution. gMemoryInfo->mSnapshotThreadsShouldIdle.ActivateEnd(); } void RestoreMemoryToLastSavedCheckpoint() { MOZ_RELEASE_ASSERT(Thread::CurrentIsMainThread()); MOZ_RELEASE_ASSERT(!gMemoryInfo->mMemoryChangesAllowed); // Restore all dirty regions that have been modified since the last // checkpoint was saved/restored. for (SortedDirtyPageSet::Iter iter = gMemoryInfo->mActiveDirty.begin(); !iter.done(); ++iter) { MemoryMove(iter.ref().mBase, iter.ref().mOriginal, PageSize); FreePageCopy(iter.ref().mOriginal); DirectWriteProtectMemory(iter.ref().mBase, PageSize, iter.ref().mExecutable); } gMemoryInfo->mActiveDirty.clear(); } void RestoreMemoryToLastSavedDiffCheckpoint() { MOZ_RELEASE_ASSERT(Thread::CurrentIsMainThread()); MOZ_RELEASE_ASSERT(!gMemoryInfo->mMemoryChangesAllowed); MOZ_RELEASE_ASSERT(gMemoryInfo->mActiveDirty.empty()); // Wait while the snapshot threads restore all pages modified since the diff // snapshot was recorded. gMemoryInfo->mSnapshotThreadsShouldRestore.ActivateBegin(); gMemoryInfo->mSnapshotThreadsShouldRestore.ActivateEnd(); } } // namespace recordreplay } // namespace mozilla