// Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "leveldb/env.h" #include "leveldb/slice.h" #include "port/port.h" #include "port/thread_annotations.h" #include "util/logging.h" #include "util/mutexlock.h" #include "util/posix_logger.h" #include "util/env_posix_test_helper.h" // HAVE_FDATASYNC is defined in the auto-generated port_config.h, which is // included by port_stdcxx.h. #if !HAVE_FDATASYNC #define fdatasync fsync #endif // !HAVE_FDATASYNC namespace leveldb { namespace { static int open_read_only_file_limit = -1; static int mmap_limit = -1; constexpr const size_t kWritableFileBufferSize = 65536; static Status PosixError(const std::string& context, int err_number) { if (err_number == ENOENT) { return Status::NotFound(context, strerror(err_number)); } else { return Status::IOError(context, strerror(err_number)); } } // Helper class to limit resource usage to avoid exhaustion. // Currently used to limit read-only file descriptors and mmap file usage // so that we do not run out of file descriptors or virtual memory, or run into // kernel performance problems for very large databases. class Limiter { public: // Limit maximum number of resources to |max_acquires|. Limiter(int max_acquires) : acquires_allowed_(max_acquires) {} Limiter(const Limiter&) = delete; Limiter operator=(const Limiter&) = delete; // If another resource is available, acquire it and return true. // Else return false. bool Acquire() { int old_acquires_allowed = acquires_allowed_.fetch_sub(1, std::memory_order_relaxed); if (old_acquires_allowed > 0) return true; acquires_allowed_.fetch_add(1, std::memory_order_relaxed); return false; } // Release a resource acquired by a previous call to Acquire() that returned // true. void Release() { acquires_allowed_.fetch_add(1, std::memory_order_relaxed); } private: // The number of available resources. // // This is a counter and is not tied to the invariants of any other class, so // it can be operated on safely using std::memory_order_relaxed. std::atomic acquires_allowed_; }; class PosixSequentialFile: public SequentialFile { private: std::string filename_; int fd_; public: PosixSequentialFile(const std::string& fname, int fd) : filename_(fname), fd_(fd) {} virtual ~PosixSequentialFile() { close(fd_); } virtual Status Read(size_t n, Slice* result, char* scratch) { Status s; while (true) { ssize_t r = read(fd_, scratch, n); if (r < 0) { if (errno == EINTR) { continue; // Retry } s = PosixError(filename_, errno); break; } *result = Slice(scratch, r); break; } return s; } virtual Status Skip(uint64_t n) { if (lseek(fd_, n, SEEK_CUR) == static_cast(-1)) { return PosixError(filename_, errno); } return Status::OK(); } }; // pread() based random-access class PosixRandomAccessFile: public RandomAccessFile { private: std::string filename_; bool temporary_fd_; // If true, fd_ is -1 and we open on every read. int fd_; Limiter* limiter_; public: PosixRandomAccessFile(const std::string& fname, int fd, Limiter* limiter) : filename_(fname), fd_(fd), limiter_(limiter) { temporary_fd_ = !limiter->Acquire(); if (temporary_fd_) { // Open file on every access. close(fd_); fd_ = -1; } } virtual ~PosixRandomAccessFile() { if (!temporary_fd_) { close(fd_); limiter_->Release(); } } virtual Status Read(uint64_t offset, size_t n, Slice* result, char* scratch) const { int fd = fd_; if (temporary_fd_) { fd = open(filename_.c_str(), O_RDONLY); if (fd < 0) { return PosixError(filename_, errno); } } Status s; ssize_t r = pread(fd, scratch, n, static_cast(offset)); *result = Slice(scratch, (r < 0) ? 0 : r); if (r < 0) { // An error: return a non-ok status s = PosixError(filename_, errno); } if (temporary_fd_) { // Close the temporary file descriptor opened earlier. close(fd); } return s; } }; // mmap() based random-access class PosixMmapReadableFile: public RandomAccessFile { private: std::string filename_; void* mmapped_region_; size_t length_; Limiter* limiter_; public: // base[0,length-1] contains the mmapped contents of the file. PosixMmapReadableFile(const std::string& fname, void* base, size_t length, Limiter* limiter) : filename_(fname), mmapped_region_(base), length_(length), limiter_(limiter) { } virtual ~PosixMmapReadableFile() { munmap(mmapped_region_, length_); limiter_->Release(); } virtual Status Read(uint64_t offset, size_t n, Slice* result, char* scratch) const { Status s; if (offset + n > length_) { *result = Slice(); s = PosixError(filename_, EINVAL); } else { *result = Slice(reinterpret_cast(mmapped_region_) + offset, n); } return s; } }; class PosixWritableFile final : public WritableFile { public: PosixWritableFile(std::string filename, int fd) : pos_(0), fd_(fd), is_manifest_(IsManifest(filename)), filename_(std::move(filename)), dirname_(Dirname(filename_)) {} ~PosixWritableFile() override { if (fd_ >= 0) { // Ignoring any potential errors Close(); } } Status Append(const Slice& data) override { size_t write_size = data.size(); const char* write_data = data.data(); // Fit as much as possible into buffer. size_t copy_size = std::min(write_size, kWritableFileBufferSize - pos_); std::memcpy(buf_ + pos_, write_data, copy_size); write_data += copy_size; write_size -= copy_size; pos_ += copy_size; if (write_size == 0) { return Status::OK(); } // Can't fit in buffer, so need to do at least one write. Status status = FlushBuffer(); if (!status.ok()) { return status; } // Small writes go to buffer, large writes are written directly. if (write_size < kWritableFileBufferSize) { std::memcpy(buf_, write_data, write_size); pos_ = write_size; return Status::OK(); } return WriteUnbuffered(write_data, write_size); } Status Close() override { Status status = FlushBuffer(); const int close_result = ::close(fd_); if (close_result < 0 && status.ok()) { status = PosixError(filename_, errno); } fd_ = -1; return status; } Status Flush() override { return FlushBuffer(); } Status Sync() override { // Ensure new files referred to by the manifest are in the filesystem. // // This needs to happen before the manifest file is flushed to disk, to // avoid crashing in a state where the manifest refers to files that are not // yet on disk. Status status = SyncDirIfManifest(); if (!status.ok()) { return status; } status = FlushBuffer(); if (status.ok() && ::fdatasync(fd_) != 0) { status = PosixError(filename_, errno); } return status; } private: Status FlushBuffer() { Status status = WriteUnbuffered(buf_, pos_); pos_ = 0; return status; } Status WriteUnbuffered(const char* data, size_t size) { while (size > 0) { ssize_t write_result = ::write(fd_, data, size); if (write_result < 0) { if (errno == EINTR) { continue; // Retry } return PosixError(filename_, errno); } data += write_result; size -= write_result; } return Status::OK(); } Status SyncDirIfManifest() { Status status; if (!is_manifest_) { return status; } int fd = ::open(dirname_.c_str(), O_RDONLY); if (fd < 0) { status = PosixError(dirname_, errno); } else { if (::fsync(fd) < 0) { status = PosixError(dirname_, errno); } ::close(fd); } return status; } // Returns the directory name in a path pointing to a file. // // Returns "." if the path does not contain any directory separator. static std::string Dirname(const std::string& filename) { std::string::size_type separator_pos = filename.rfind('/'); if (separator_pos == std::string::npos) { return std::string("."); } // The filename component should not contain a path separator. If it does, // the splitting was done incorrectly. assert(filename.find('/', separator_pos + 1) == std::string::npos); return filename.substr(0, separator_pos); } // Extracts the file name from a path pointing to a file. // // The returned Slice points to |filename|'s data buffer, so it is only valid // while |filename| is alive and unchanged. static Slice Basename(const std::string& filename) { std::string::size_type separator_pos = filename.rfind('/'); if (separator_pos == std::string::npos) { return Slice(filename); } // The filename component should not contain a path separator. If it does, // the splitting was done incorrectly. assert(filename.find('/', separator_pos + 1) == std::string::npos); return Slice(filename.data() + separator_pos + 1, filename.length() - separator_pos - 1); } // True if the given file is a manifest file. static bool IsManifest(const std::string& filename) { return Basename(filename).starts_with("MANIFEST"); } // buf_[0, pos_ - 1] contains data to be written to fd_. char buf_[kWritableFileBufferSize]; size_t pos_; int fd_; const bool is_manifest_; // True if the file's name starts with MANIFEST. const std::string filename_; const std::string dirname_; // The directory of filename_. }; static int LockOrUnlock(int fd, bool lock) { errno = 0; struct flock f; memset(&f, 0, sizeof(f)); f.l_type = (lock ? F_WRLCK : F_UNLCK); f.l_whence = SEEK_SET; f.l_start = 0; f.l_len = 0; // Lock/unlock entire file return fcntl(fd, F_SETLK, &f); } class PosixFileLock : public FileLock { public: int fd_; std::string name_; }; // Set of locked files. We keep a separate set instead of just // relying on fcntrl(F_SETLK) since fcntl(F_SETLK) does not provide // any protection against multiple uses from the same process. class PosixLockTable { private: port::Mutex mu_; std::set locked_files_ GUARDED_BY(mu_); public: bool Insert(const std::string& fname) LOCKS_EXCLUDED(mu_) { MutexLock l(&mu_); return locked_files_.insert(fname).second; } void Remove(const std::string& fname) LOCKS_EXCLUDED(mu_) { MutexLock l(&mu_); locked_files_.erase(fname); } }; class PosixEnv : public Env { public: PosixEnv(); virtual ~PosixEnv() { char msg[] = "Destroying Env::Default()\n"; fwrite(msg, 1, sizeof(msg), stderr); abort(); } virtual Status NewSequentialFile(const std::string& fname, SequentialFile** result) { int fd = open(fname.c_str(), O_RDONLY); if (fd < 0) { *result = nullptr; return PosixError(fname, errno); } else { *result = new PosixSequentialFile(fname, fd); return Status::OK(); } } virtual Status NewRandomAccessFile(const std::string& fname, RandomAccessFile** result) { *result = nullptr; Status s; int fd = open(fname.c_str(), O_RDONLY); if (fd < 0) { s = PosixError(fname, errno); } else if (mmap_limit_.Acquire()) { uint64_t size; s = GetFileSize(fname, &size); if (s.ok()) { void* base = mmap(nullptr, size, PROT_READ, MAP_SHARED, fd, 0); if (base != MAP_FAILED) { *result = new PosixMmapReadableFile(fname, base, size, &mmap_limit_); } else { s = PosixError(fname, errno); } } close(fd); if (!s.ok()) { mmap_limit_.Release(); } } else { *result = new PosixRandomAccessFile(fname, fd, &fd_limit_); } return s; } virtual Status NewWritableFile(const std::string& fname, WritableFile** result) { Status s; int fd = open(fname.c_str(), O_TRUNC | O_WRONLY | O_CREAT, 0644); if (fd < 0) { *result = nullptr; s = PosixError(fname, errno); } else { *result = new PosixWritableFile(fname, fd); } return s; } virtual Status NewAppendableFile(const std::string& fname, WritableFile** result) { Status s; int fd = open(fname.c_str(), O_APPEND | O_WRONLY | O_CREAT, 0644); if (fd < 0) { *result = nullptr; s = PosixError(fname, errno); } else { *result = new PosixWritableFile(fname, fd); } return s; } virtual bool FileExists(const std::string& fname) { return access(fname.c_str(), F_OK) == 0; } virtual Status GetChildren(const std::string& dir, std::vector* result) { result->clear(); DIR* d = opendir(dir.c_str()); if (d == nullptr) { return PosixError(dir, errno); } struct dirent* entry; while ((entry = readdir(d)) != nullptr) { result->push_back(entry->d_name); } closedir(d); return Status::OK(); } virtual Status DeleteFile(const std::string& fname) { Status result; if (unlink(fname.c_str()) != 0) { result = PosixError(fname, errno); } return result; } virtual Status CreateDir(const std::string& name) { Status result; if (mkdir(name.c_str(), 0755) != 0) { result = PosixError(name, errno); } return result; } virtual Status DeleteDir(const std::string& name) { Status result; if (rmdir(name.c_str()) != 0) { result = PosixError(name, errno); } return result; } virtual Status GetFileSize(const std::string& fname, uint64_t* size) { Status s; struct stat sbuf; if (stat(fname.c_str(), &sbuf) != 0) { *size = 0; s = PosixError(fname, errno); } else { *size = sbuf.st_size; } return s; } virtual Status RenameFile(const std::string& src, const std::string& target) { Status result; if (rename(src.c_str(), target.c_str()) != 0) { result = PosixError(src, errno); } return result; } virtual Status LockFile(const std::string& fname, FileLock** lock) { *lock = nullptr; Status result; int fd = open(fname.c_str(), O_RDWR | O_CREAT, 0644); if (fd < 0) { result = PosixError(fname, errno); } else if (!locks_.Insert(fname)) { close(fd); result = Status::IOError("lock " + fname, "already held by process"); } else if (LockOrUnlock(fd, true) == -1) { result = PosixError("lock " + fname, errno); close(fd); locks_.Remove(fname); } else { PosixFileLock* my_lock = new PosixFileLock; my_lock->fd_ = fd; my_lock->name_ = fname; *lock = my_lock; } return result; } virtual Status UnlockFile(FileLock* lock) { PosixFileLock* my_lock = reinterpret_cast(lock); Status result; if (LockOrUnlock(my_lock->fd_, false) == -1) { result = PosixError("unlock", errno); } locks_.Remove(my_lock->name_); close(my_lock->fd_); delete my_lock; return result; } virtual void Schedule(void (*function)(void*), void* arg); virtual void StartThread(void (*function)(void* arg), void* arg); virtual Status GetTestDirectory(std::string* result) { const char* env = getenv("TEST_TMPDIR"); if (env && env[0] != '\0') { *result = env; } else { char buf[100]; snprintf(buf, sizeof(buf), "/tmp/leveldbtest-%d", int(geteuid())); *result = buf; } // Directory may already exist CreateDir(*result); return Status::OK(); } virtual Status NewLogger(const std::string& fname, Logger** result) { FILE* f = fopen(fname.c_str(), "w"); if (f == nullptr) { *result = nullptr; return PosixError(fname, errno); } else { *result = new PosixLogger(f); return Status::OK(); } } virtual uint64_t NowMicros() { struct timeval tv; gettimeofday(&tv, nullptr); return static_cast(tv.tv_sec) * 1000000 + tv.tv_usec; } virtual void SleepForMicroseconds(int micros) { usleep(micros); } private: void BackgroundThreadMain(); static void BackgroundThreadEntryPoint(PosixEnv* env) { env->BackgroundThreadMain(); } // Stores the work item data in a Schedule() call. // // Instances are constructed on the thread calling Schedule() and used on the // background thread. // // This structure is thread-safe beacuse it is immutable. struct BackgroundWorkItem { explicit BackgroundWorkItem(void (*function)(void* arg), void* arg) : function(function), arg(arg) {} void (* const function)(void*); void* const arg; }; port::Mutex background_work_mutex_; port::CondVar background_work_cv_ GUARDED_BY(background_work_mutex_); bool started_background_thread_ GUARDED_BY(background_work_mutex_); std::queue background_work_queue_ GUARDED_BY(background_work_mutex_); PosixLockTable locks_; Limiter mmap_limit_; Limiter fd_limit_; }; // Return the maximum number of concurrent mmaps. static int MaxMmaps() { if (mmap_limit >= 0) { return mmap_limit; } // Up to 1000 mmaps for 64-bit binaries; none for smaller pointer sizes. mmap_limit = sizeof(void*) >= 8 ? 1000 : 0; return mmap_limit; } // Return the maximum number of read-only files to keep open. static intptr_t MaxOpenFiles() { if (open_read_only_file_limit >= 0) { return open_read_only_file_limit; } struct rlimit rlim; if (getrlimit(RLIMIT_NOFILE, &rlim)) { // getrlimit failed, fallback to hard-coded default. open_read_only_file_limit = 50; } else if (rlim.rlim_cur == RLIM_INFINITY) { open_read_only_file_limit = std::numeric_limits::max(); } else { // Allow use of 20% of available file descriptors for read-only files. open_read_only_file_limit = rlim.rlim_cur / 5; } return open_read_only_file_limit; } PosixEnv::PosixEnv() : background_work_cv_(&background_work_mutex_), started_background_thread_(false), mmap_limit_(MaxMmaps()), fd_limit_(MaxOpenFiles()) { } void PosixEnv::Schedule( void (*background_work_function)(void* background_work_arg), void* background_work_arg) { MutexLock lock(&background_work_mutex_); // Start the background thread, if we haven't done so already. if (!started_background_thread_) { started_background_thread_ = true; std::thread background_thread(PosixEnv::BackgroundThreadEntryPoint, this); background_thread.detach(); } // If the queue is empty, the background thread may be waiting for work. if (background_work_queue_.empty()) { background_work_cv_.Signal(); } background_work_queue_.emplace(background_work_function, background_work_arg); } void PosixEnv::BackgroundThreadMain() { while (true) { background_work_mutex_.Lock(); // Wait until there is work to be done. while (background_work_queue_.empty()) { background_work_cv_.Wait(); } assert(!background_work_queue_.empty()); auto background_work_function = background_work_queue_.front().function; void* background_work_arg = background_work_queue_.front().arg; background_work_queue_.pop(); background_work_mutex_.Unlock(); background_work_function(background_work_arg); } } } // namespace void PosixEnv::StartThread(void (*thread_main)(void* thread_main_arg), void* thread_main_arg) { std::thread new_thread(thread_main, thread_main_arg); new_thread.detach(); } static pthread_once_t once = PTHREAD_ONCE_INIT; static Env* default_env; static void InitDefaultEnv() { default_env = new PosixEnv; } void EnvPosixTestHelper::SetReadOnlyFDLimit(int limit) { assert(default_env == nullptr); open_read_only_file_limit = limit; } void EnvPosixTestHelper::SetReadOnlyMMapLimit(int limit) { assert(default_env == nullptr); mmap_limit = limit; } Env* Env::Default() { pthread_once(&once, InitDefaultEnv); return default_env; } } // namespace leveldb