// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/memory/discardable_shared_memory.h" #include #include #include "base/atomicops.h" #include "base/bits.h" #include "base/logging.h" #include "base/memory/shared_memory_tracker.h" #include "base/numerics/safe_math.h" #include "base/process/process_metrics.h" #include "base/trace_event/memory_allocator_dump.h" #include "base/trace_event/process_memory_dump.h" #include "build/build_config.h" #if defined(OS_POSIX) && !defined(OS_NACL) // For madvise() which is available on all POSIX compatible systems. #include #endif #if defined(OS_ANDROID) #include "third_party/ashmem/ashmem.h" #endif #if defined(OS_WIN) #include "base/win/windows_version.h" #endif namespace base { namespace { // Use a machine-sized pointer as atomic type. It will use the Atomic32 or // Atomic64 routines, depending on the architecture. typedef intptr_t AtomicType; typedef uintptr_t UAtomicType; // Template specialization for timestamp serialization/deserialization. This // is used to serialize timestamps using Unix time on systems where AtomicType // does not have enough precision to contain a timestamp in the standard // serialized format. template Time TimeFromWireFormat(int64_t value); template int64_t TimeToWireFormat(Time time); // Serialize to Unix time when using 4-byte wire format. // Note: 19 January 2038, this will cease to work. template <> Time ALLOW_UNUSED_TYPE TimeFromWireFormat<4>(int64_t value) { return value ? Time::UnixEpoch() + TimeDelta::FromSeconds(value) : Time(); } template <> int64_t ALLOW_UNUSED_TYPE TimeToWireFormat<4>(Time time) { return time > Time::UnixEpoch() ? (time - Time::UnixEpoch()).InSeconds() : 0; } // Standard serialization format when using 8-byte wire format. template <> Time ALLOW_UNUSED_TYPE TimeFromWireFormat<8>(int64_t value) { return Time::FromInternalValue(value); } template <> int64_t ALLOW_UNUSED_TYPE TimeToWireFormat<8>(Time time) { return time.ToInternalValue(); } struct SharedState { enum LockState { UNLOCKED = 0, LOCKED = 1 }; explicit SharedState(AtomicType ivalue) { value.i = ivalue; } SharedState(LockState lock_state, Time timestamp) { int64_t wire_timestamp = TimeToWireFormat(timestamp); DCHECK_GE(wire_timestamp, 0); DCHECK_EQ(lock_state & ~1, 0); value.u = (static_cast(wire_timestamp) << 1) | lock_state; } LockState GetLockState() const { return static_cast(value.u & 1); } Time GetTimestamp() const { return TimeFromWireFormat(value.u >> 1); } // Bit 1: Lock state. Bit is set when locked. // Bit 2..sizeof(AtomicType)*8: Usage timestamp. NULL time when locked or // purged. union { AtomicType i; UAtomicType u; } value; }; // Shared state is stored at offset 0 in shared memory segments. SharedState* SharedStateFromSharedMemory(const SharedMemory& shared_memory) { DCHECK(shared_memory.memory()); return static_cast(shared_memory.memory()); } // Round up |size| to a multiple of page size. size_t AlignToPageSize(size_t size) { return bits::Align(size, base::GetPageSize()); } // LockPages/UnlockPages are platform-native discardable page management // helper functions. Both expect |offset| to be specified relative to the // base address at which |memory| is mapped, and that |offset| and |length| // are page-aligned by the caller. // Returns SUCCESS on platforms which do not support discardable pages. DiscardableSharedMemory::LockResult LockPages(const SharedMemory& memory, size_t offset, size_t length) { #if defined(OS_ANDROID) SharedMemoryHandle handle = memory.handle(); if (handle.IsValid()) { int pin_result = ashmem_pin_region(handle.GetHandle(), offset, length); if (pin_result == ASHMEM_WAS_PURGED) return DiscardableSharedMemory::PURGED; if (pin_result < 0) return DiscardableSharedMemory::FAILED; } #endif return DiscardableSharedMemory::SUCCESS; } // UnlockPages() is a no-op on platforms not supporting discardable pages. void UnlockPages(const SharedMemory& memory, size_t offset, size_t length) { #if defined(OS_ANDROID) SharedMemoryHandle handle = memory.handle(); if (handle.IsValid()) { int unpin_result = ashmem_unpin_region(handle.GetHandle(), offset, length); DCHECK_EQ(0, unpin_result); } #endif } } // namespace DiscardableSharedMemory::DiscardableSharedMemory() : mapped_size_(0), locked_page_count_(0) { } DiscardableSharedMemory::DiscardableSharedMemory( SharedMemoryHandle shared_memory_handle) : shared_memory_(shared_memory_handle, false), mapped_size_(0), locked_page_count_(0) { } DiscardableSharedMemory::~DiscardableSharedMemory() = default; bool DiscardableSharedMemory::CreateAndMap(size_t size) { CheckedNumeric checked_size = size; checked_size += AlignToPageSize(sizeof(SharedState)); if (!checked_size.IsValid()) return false; if (!shared_memory_.CreateAndMapAnonymous(checked_size.ValueOrDie())) return false; mapped_size_ = shared_memory_.mapped_size() - AlignToPageSize(sizeof(SharedState)); locked_page_count_ = AlignToPageSize(mapped_size_) / base::GetPageSize(); #if DCHECK_IS_ON() for (size_t page = 0; page < locked_page_count_; ++page) locked_pages_.insert(page); #endif DCHECK(last_known_usage_.is_null()); SharedState new_state(SharedState::LOCKED, Time()); subtle::Release_Store(&SharedStateFromSharedMemory(shared_memory_)->value.i, new_state.value.i); return true; } bool DiscardableSharedMemory::Map(size_t size) { if (!shared_memory_.Map(AlignToPageSize(sizeof(SharedState)) + size)) return false; mapped_size_ = shared_memory_.mapped_size() - AlignToPageSize(sizeof(SharedState)); locked_page_count_ = AlignToPageSize(mapped_size_) / base::GetPageSize(); #if DCHECK_IS_ON() for (size_t page = 0; page < locked_page_count_; ++page) locked_pages_.insert(page); #endif return true; } bool DiscardableSharedMemory::Unmap() { if (!shared_memory_.Unmap()) return false; locked_page_count_ = 0; #if DCHECK_IS_ON() locked_pages_.clear(); #endif mapped_size_ = 0; return true; } DiscardableSharedMemory::LockResult DiscardableSharedMemory::Lock( size_t offset, size_t length) { DCHECK_EQ(AlignToPageSize(offset), offset); DCHECK_EQ(AlignToPageSize(length), length); // Calls to this function must be synchronized properly. DFAKE_SCOPED_LOCK(thread_collision_warner_); DCHECK(shared_memory_.memory()); // We need to successfully acquire the platform independent lock before // individual pages can be locked. if (!locked_page_count_) { // Return false when instance has been purged or not initialized properly // by checking if |last_known_usage_| is NULL. if (last_known_usage_.is_null()) return FAILED; SharedState old_state(SharedState::UNLOCKED, last_known_usage_); SharedState new_state(SharedState::LOCKED, Time()); SharedState result(subtle::Acquire_CompareAndSwap( &SharedStateFromSharedMemory(shared_memory_)->value.i, old_state.value.i, new_state.value.i)); if (result.value.u != old_state.value.u) { // Update |last_known_usage_| in case the above CAS failed because of // an incorrect timestamp. last_known_usage_ = result.GetTimestamp(); return FAILED; } } // Zero for length means "everything onward". if (!length) length = AlignToPageSize(mapped_size_) - offset; size_t start = offset / base::GetPageSize(); size_t end = start + length / base::GetPageSize(); DCHECK_LE(start, end); DCHECK_LE(end, AlignToPageSize(mapped_size_) / base::GetPageSize()); // Add pages to |locked_page_count_|. // Note: Locking a page that is already locked is an error. locked_page_count_ += end - start; #if DCHECK_IS_ON() // Detect incorrect usage by keeping track of exactly what pages are locked. for (auto page = start; page < end; ++page) { auto result = locked_pages_.insert(page); DCHECK(result.second); } DCHECK_EQ(locked_pages_.size(), locked_page_count_); #endif // Always behave as if memory was purged when trying to lock a 0 byte segment. if (!length) return PURGED; // Ensure that the platform won't discard the required pages. return LockPages(shared_memory_, AlignToPageSize(sizeof(SharedState)) + offset, length); } void DiscardableSharedMemory::Unlock(size_t offset, size_t length) { DCHECK_EQ(AlignToPageSize(offset), offset); DCHECK_EQ(AlignToPageSize(length), length); // Calls to this function must be synchronized properly. DFAKE_SCOPED_LOCK(thread_collision_warner_); // Passing zero for |length| means "everything onward". Note that |length| may // still be zero after this calculation, e.g. if |mapped_size_| is zero. if (!length) length = AlignToPageSize(mapped_size_) - offset; DCHECK(shared_memory_.memory()); // Allow the pages to be discarded by the platform, if supported. UnlockPages(shared_memory_, AlignToPageSize(sizeof(SharedState)) + offset, length); size_t start = offset / base::GetPageSize(); size_t end = start + length / base::GetPageSize(); DCHECK_LE(start, end); DCHECK_LE(end, AlignToPageSize(mapped_size_) / base::GetPageSize()); // Remove pages from |locked_page_count_|. // Note: Unlocking a page that is not locked is an error. DCHECK_GE(locked_page_count_, end - start); locked_page_count_ -= end - start; #if DCHECK_IS_ON() // Detect incorrect usage by keeping track of exactly what pages are locked. for (auto page = start; page < end; ++page) { auto erased_count = locked_pages_.erase(page); DCHECK_EQ(1u, erased_count); } DCHECK_EQ(locked_pages_.size(), locked_page_count_); #endif // Early out and avoid releasing the platform independent lock if some pages // are still locked. if (locked_page_count_) return; Time current_time = Now(); DCHECK(!current_time.is_null()); SharedState old_state(SharedState::LOCKED, Time()); SharedState new_state(SharedState::UNLOCKED, current_time); // Note: timestamp cannot be NULL as that is a unique value used when // locked or purged. DCHECK(!new_state.GetTimestamp().is_null()); // Timestamp precision should at least be accurate to the second. DCHECK_EQ((new_state.GetTimestamp() - Time::UnixEpoch()).InSeconds(), (current_time - Time::UnixEpoch()).InSeconds()); SharedState result(subtle::Release_CompareAndSwap( &SharedStateFromSharedMemory(shared_memory_)->value.i, old_state.value.i, new_state.value.i)); DCHECK_EQ(old_state.value.u, result.value.u); last_known_usage_ = current_time; } void* DiscardableSharedMemory::memory() const { return reinterpret_cast(shared_memory_.memory()) + AlignToPageSize(sizeof(SharedState)); } bool DiscardableSharedMemory::Purge(Time current_time) { // Calls to this function must be synchronized properly. DFAKE_SCOPED_LOCK(thread_collision_warner_); DCHECK(shared_memory_.memory()); SharedState old_state(SharedState::UNLOCKED, last_known_usage_); SharedState new_state(SharedState::UNLOCKED, Time()); SharedState result(subtle::Acquire_CompareAndSwap( &SharedStateFromSharedMemory(shared_memory_)->value.i, old_state.value.i, new_state.value.i)); // Update |last_known_usage_| to |current_time| if the memory is locked. This // allows the caller to determine if purging failed because last known usage // was incorrect or memory was locked. In the second case, the caller should // most likely wait for some amount of time before attempting to purge the // the memory again. if (result.value.u != old_state.value.u) { last_known_usage_ = result.GetLockState() == SharedState::LOCKED ? current_time : result.GetTimestamp(); return false; } // The next section will release as much resource as can be done // from the purging process, until the client process notices the // purge and releases its own references. // Note: this memory will not be accessed again. The segment will be // freed asynchronously at a later time, so just do the best // immediately. #if defined(OS_POSIX) && !defined(OS_NACL) // Linux and Android provide MADV_REMOVE which is preferred as it has a // behavior that can be verified in tests. Other POSIX flavors (MacOSX, BSDs), // provide MADV_FREE which has the same result but memory is purged lazily. #if defined(OS_LINUX) || defined(OS_ANDROID) #define MADV_PURGE_ARGUMENT MADV_REMOVE #elif defined(OS_MACOSX) // MADV_FREE_REUSABLE is similar to MADV_FREE, but also marks the pages with the // reusable bit, which allows both Activity Monitor and memory-infra to // correctly track the pages. #define MADV_PURGE_ARGUMENT MADV_FREE_REUSABLE #else #define MADV_PURGE_ARGUMENT MADV_FREE #endif // Advise the kernel to remove resources associated with purged pages. // Subsequent accesses of memory pages will succeed, but might result in // zero-fill-on-demand pages. if (madvise(reinterpret_cast(shared_memory_.memory()) + AlignToPageSize(sizeof(SharedState)), AlignToPageSize(mapped_size_), MADV_PURGE_ARGUMENT)) { DPLOG(ERROR) << "madvise() failed"; } #elif defined(OS_WIN) if (base::win::GetVersion() >= base::win::VERSION_WIN8_1) { // Discard the purged pages, which releases the physical storage (resident // memory, compressed or swapped), but leaves them reserved & committed. // This does not free commit for use by other applications, but allows the // system to avoid compressing/swapping these pages to free physical memory. static const auto discard_virtual_memory = reinterpret_cast(GetProcAddress( GetModuleHandle(L"kernel32.dll"), "DiscardVirtualMemory")); if (discard_virtual_memory) { DWORD discard_result = discard_virtual_memory( reinterpret_cast(shared_memory_.memory()) + AlignToPageSize(sizeof(SharedState)), AlignToPageSize(mapped_size_)); if (discard_result != ERROR_SUCCESS) { DLOG(DCHECK) << "DiscardVirtualMemory() failed in Purge(): " << logging::SystemErrorCodeToString(discard_result); } } } #endif last_known_usage_ = Time(); return true; } bool DiscardableSharedMemory::IsMemoryResident() const { DCHECK(shared_memory_.memory()); SharedState result(subtle::NoBarrier_Load( &SharedStateFromSharedMemory(shared_memory_)->value.i)); return result.GetLockState() == SharedState::LOCKED || !result.GetTimestamp().is_null(); } bool DiscardableSharedMemory::IsMemoryLocked() const { DCHECK(shared_memory_.memory()); SharedState result(subtle::NoBarrier_Load( &SharedStateFromSharedMemory(shared_memory_)->value.i)); return result.GetLockState() == SharedState::LOCKED; } void DiscardableSharedMemory::Close() { shared_memory_.Close(); } void DiscardableSharedMemory::CreateSharedMemoryOwnershipEdge( trace_event::MemoryAllocatorDump* local_segment_dump, trace_event::ProcessMemoryDump* pmd, bool is_owned) const { auto* shared_memory_dump = SharedMemoryTracker::GetOrCreateSharedMemoryDump(&shared_memory_, pmd); // TODO(ssid): Clean this by a new api to inherit size of parent dump once the // we send the full PMD and calculate sizes inside chrome, crbug.com/704203. size_t resident_size = shared_memory_dump->GetSizeInternal(); local_segment_dump->AddScalar(trace_event::MemoryAllocatorDump::kNameSize, trace_event::MemoryAllocatorDump::kUnitsBytes, resident_size); // By creating an edge with a higher |importance| (w.r.t non-owned dumps) // the tracing UI will account the effective size of the segment to the // client instead of manager. // TODO(ssid): Define better constants in MemoryAllocatorDump for importance // values, crbug.com/754793. const int kImportance = is_owned ? 2 : 0; auto shared_memory_guid = shared_memory_.mapped_id(); local_segment_dump->AddString("id", "hash", shared_memory_guid.ToString()); // Owned discardable segments which are allocated by client process, could // have been cleared by the discardable manager. So, the segment need not // exist in memory and weak dumps are created to indicate the UI that the dump // should exist only if the manager also created the global dump edge. if (is_owned) { pmd->CreateWeakSharedMemoryOwnershipEdge(local_segment_dump->guid(), shared_memory_guid, kImportance); } else { pmd->CreateSharedMemoryOwnershipEdge(local_segment_dump->guid(), shared_memory_guid, kImportance); } } Time DiscardableSharedMemory::Now() const { return Time::Now(); } } // namespace base