// 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. #ifndef BASE_MEMORY_DISCARDABLE_SHARED_MEMORY_H_ #define BASE_MEMORY_DISCARDABLE_SHARED_MEMORY_H_ #include "base/base_export.h" #include "base/logging.h" #include "base/memory/shared_memory.h" #include "base/threading/thread_collision_warner.h" #include "base/time/time.h" #if DCHECK_IS_ON() #include #endif // Define DISCARDABLE_SHARED_MEMORY_SHRINKING if platform supports shrinking // of discardable shared memory segments. #if defined(OS_POSIX) && !defined(OS_ANDROID) #define DISCARDABLE_SHARED_MEMORY_SHRINKING #endif namespace base { // Platform abstraction for discardable shared memory. // // This class is not thread-safe. Clients are responsible for synchronizing // access to an instance of this class. class BASE_EXPORT DiscardableSharedMemory { public: enum LockResult { SUCCESS, PURGED, FAILED }; DiscardableSharedMemory(); // Create a new DiscardableSharedMemory object from an existing, open shared // memory file. Memory must be locked. explicit DiscardableSharedMemory(SharedMemoryHandle handle); // Closes any open files. virtual ~DiscardableSharedMemory(); // Creates and maps a locked DiscardableSharedMemory object with |size|. // Returns true on success and false on failure. bool CreateAndMap(size_t size); // Maps the locked discardable memory into the caller's address space. // Returns true on success, false otherwise. bool Map(size_t size); // Unmaps the discardable shared memory from the caller's address space. // Returns true if successful; returns false on error or if the memory is // not mapped. bool Unmap(); // The actual size of the mapped memory (may be larger than requested). size_t mapped_size() const { return mapped_size_; } // Returns a shared memory handle for this DiscardableSharedMemory object. SharedMemoryHandle handle() const { return shared_memory_.handle(); } // Locks a range of memory so that it will not be purged by the system. // The range of memory must be unlocked. The result of trying to lock an // already locked range is undefined. |offset| and |length| must both be // a multiple of the page size as returned by GetPageSize(). // Passing 0 for |length| means "everything onward". // Returns SUCCESS if range was successfully locked and the memory is still // resident, PURGED if range was successfully locked but has been purged // since last time it was locked and FAILED if range could not be locked. // Locking can fail for two reasons; object might have been purged, our // last known usage timestamp might be out of date. Last known usage time // is updated to the actual last usage timestamp if memory is still resident // or 0 if not. LockResult Lock(size_t offset, size_t length); // Unlock a previously successfully locked range of memory. The range of // memory must be locked. The result of trying to unlock a not // previously locked range is undefined. // |offset| and |length| must both be a multiple of the page size as returned // by GetPageSize(). // Passing 0 for |length| means "everything onward". void Unlock(size_t offset, size_t length); // Gets a pointer to the opened discardable memory space. Discardable memory // must have been mapped via Map(). void* memory() const; // Returns the last known usage time for DiscardableSharedMemory object. This // may be earlier than the "true" usage time when memory has been used by a // different process. Returns NULL time if purged. Time last_known_usage() const { return last_known_usage_; } // This returns true and sets |last_known_usage_| to 0 if // DiscardableSharedMemory object was successfully purged. Purging can fail // for two reasons; object might be locked or our last known usage timestamp // might be out of date. Last known usage time is updated to |current_time| // if locked or the actual last usage timestamp if unlocked. It is often // necessary to call this function twice for the object to successfully be // purged. First call, updates |last_known_usage_|. Second call, successfully // purges the object using the updated |last_known_usage_|. // Note: there is no guarantee that multiple calls to this function will // successfully purge object. DiscardableSharedMemory object might be locked // or another thread/process might be able to lock and unlock it in between // each call. bool Purge(Time current_time); // Returns true if memory is still resident. bool IsMemoryResident() const; // Closes the open discardable memory segment. // It is safe to call Close repeatedly. void Close(); // Shares the discardable memory segment to another process. Attempts to // create a platform-specific |new_handle| which can be used in a remote // process to access the discardable memory segment. |new_handle| is an // output parameter to receive the handle for use in the remote process. // Returns true on success, false otherwise. bool ShareToProcess(ProcessHandle process_handle, SharedMemoryHandle* new_handle) { return shared_memory_.ShareToProcess(process_handle, new_handle); } #if defined(DISCARDABLE_SHARED_MEMORY_SHRINKING) // Release as much memory as possible to the OS. The change in size will // be reflected by the return value of mapped_size(). void Shrink(); #endif private: // Virtual for tests. virtual Time Now() const; SharedMemory shared_memory_; size_t mapped_size_; size_t locked_page_count_; #if DCHECK_IS_ON() std::set locked_pages_; #endif // Implementation is not thread-safe but still usable if clients are // synchronized somehow. Use a collision warner to detect incorrect usage. DFAKE_MUTEX(thread_collision_warner_); Time last_known_usage_; DISALLOW_COPY_AND_ASSIGN(DiscardableSharedMemory); }; } // namespace base #endif // BASE_MEMORY_DISCARDABLE_SHARED_MEMORY_H_