from __future__ import annotations import contextlib import io import threading import uuid import warnings from typing import Any, Hashable from xarray.backends.locks import acquire from xarray.backends.lru_cache import LRUCache from xarray.core import utils from xarray.core.options import OPTIONS # Global cache for storing open files. FILE_CACHE: LRUCache[Any, io.IOBase] = LRUCache( maxsize=OPTIONS["file_cache_maxsize"], on_evict=lambda k, v: v.close() ) assert FILE_CACHE.maxsize, "file cache must be at least size one" REF_COUNTS: dict[Any, int] = {} _DEFAULT_MODE = utils.ReprObject("") class FileManager: """Manager for acquiring and closing a file object. Use FileManager subclasses (CachingFileManager in particular) on backend storage classes to automatically handle issues related to keeping track of many open files and transferring them between multiple processes. """ def acquire(self, needs_lock=True): """Acquire the file object from this manager.""" raise NotImplementedError() def acquire_context(self, needs_lock=True): """Context manager for acquiring a file. Yields a file object. The context manager unwinds any actions taken as part of acquisition (i.e., removes it from any cache) if an exception is raised from the context. It *does not* automatically close the file. """ raise NotImplementedError() def close(self, needs_lock=True): """Close the file object associated with this manager, if needed.""" raise NotImplementedError() class CachingFileManager(FileManager): """Wrapper for automatically opening and closing file objects. Unlike files, CachingFileManager objects can be safely pickled and passed between processes. They should be explicitly closed to release resources, but a per-process least-recently-used cache for open files ensures that you can safely create arbitrarily large numbers of FileManager objects. Don't directly close files acquired from a FileManager. Instead, call FileManager.close(), which ensures that closed files are removed from the cache as well. Example usage: manager = FileManager(open, 'example.txt', mode='w') f = manager.acquire() f.write(...) manager.close() # ensures file is closed Note that as long as previous files are still cached, acquiring a file multiple times from the same FileManager is essentially free: f1 = manager.acquire() f2 = manager.acquire() assert f1 is f2 """ def __init__( self, opener, *args, mode=_DEFAULT_MODE, kwargs=None, lock=None, cache=None, manager_id: Hashable | None = None, ref_counts=None, ): """Initialize a CachingFileManager. The cache, manager_id and ref_counts arguments exist solely to facilitate dependency injection, and should only be set for tests. Parameters ---------- opener : callable Function that when called like ``opener(*args, **kwargs)`` returns an open file object. The file object must implement a ``close()`` method. *args Positional arguments for opener. A ``mode`` argument should be provided as a keyword argument (see below). All arguments must be hashable. mode : optional If provided, passed as a keyword argument to ``opener`` along with ``**kwargs``. ``mode='w' `` has special treatment: after the first call it is replaced by ``mode='a'`` in all subsequent function to avoid overriding the newly created file. kwargs : dict, optional Keyword arguments for opener, excluding ``mode``. All values must be hashable. lock : duck-compatible threading.Lock, optional Lock to use when modifying the cache inside acquire() and close(). By default, uses a new threading.Lock() object. If set, this object should be pickleable. cache : MutableMapping, optional Mapping to use as a cache for open files. By default, uses xarray's global LRU file cache. Because ``cache`` typically points to a global variable and contains non-picklable file objects, an unpickled FileManager objects will be restored with the default cache. manager_id : hashable, optional Identifier for this CachingFileManager. ref_counts : dict, optional Optional dict to use for keeping track the number of references to the same file. """ self._opener = opener self._args = args self._mode = mode self._kwargs = {} if kwargs is None else dict(kwargs) self._use_default_lock = lock is None or lock is False self._lock = threading.Lock() if self._use_default_lock else lock # cache[self._key] stores the file associated with this object. if cache is None: cache = FILE_CACHE self._cache = cache if manager_id is None: # Each call to CachingFileManager should separately open files. manager_id = str(uuid.uuid4()) self._manager_id = manager_id self._key = self._make_key() # ref_counts[self._key] stores the number of CachingFileManager objects # in memory referencing this same file. We use this to know if we can # close a file when the manager is deallocated. if ref_counts is None: ref_counts = REF_COUNTS self._ref_counter = _RefCounter(ref_counts) self._ref_counter.increment(self._key) def _make_key(self): """Make a key for caching files in the LRU cache.""" value = ( self._opener, self._args, "a" if self._mode == "w" else self._mode, tuple(sorted(self._kwargs.items())), self._manager_id, ) return _HashedSequence(value) @contextlib.contextmanager def _optional_lock(self, needs_lock): """Context manager for optionally acquiring a lock.""" if needs_lock: with self._lock: yield else: yield def acquire(self, needs_lock=True): """Acquire a file object from the manager. A new file is only opened if it has expired from the least-recently-used cache. This method uses a lock, which ensures that it is thread-safe. You can safely acquire a file in multiple threads at the same time, as long as the underlying file object is thread-safe. Returns ------- file-like An open file object, as returned by ``opener(*args, **kwargs)``. """ file, _ = self._acquire_with_cache_info(needs_lock) return file @contextlib.contextmanager def acquire_context(self, needs_lock=True): """Context manager for acquiring a file.""" file, cached = self._acquire_with_cache_info(needs_lock) try: yield file except Exception: if not cached: self.close(needs_lock) raise def _acquire_with_cache_info(self, needs_lock=True): """Acquire a file, returning the file and whether it was cached.""" with self._optional_lock(needs_lock): try: file = self._cache[self._key] except KeyError: kwargs = self._kwargs if self._mode is not _DEFAULT_MODE: kwargs = kwargs.copy() kwargs["mode"] = self._mode file = self._opener(*self._args, **kwargs) if self._mode == "w": # ensure file doesn't get overridden when opened again self._mode = "a" self._cache[self._key] = file return file, False else: return file, True def close(self, needs_lock=True): """Explicitly close any associated file object (if necessary).""" # TODO: remove needs_lock if/when we have a reentrant lock in # dask.distributed: https://github.com/dask/dask/issues/3832 with self._optional_lock(needs_lock): default = None file = self._cache.pop(self._key, default) if file is not None: file.close() def __del__(self) -> None: # If we're the only CachingFileManger referencing a unclosed file, # remove it from the cache upon garbage collection. # # We keep track of our own reference count because we don't want to # close files if another identical file manager needs it. This can # happen if a CachingFileManager is pickled and unpickled without # closing the original file. ref_count = self._ref_counter.decrement(self._key) if not ref_count and self._key in self._cache: if acquire(self._lock, blocking=False): # Only close files if we can do so immediately. try: self.close(needs_lock=False) finally: self._lock.release() if OPTIONS["warn_for_unclosed_files"]: warnings.warn( f"deallocating {self}, but file is not already closed. " "This may indicate a bug.", RuntimeWarning, stacklevel=2, ) def __getstate__(self): """State for pickling.""" # cache is intentionally omitted: we don't want to try to serialize # these global objects. lock = None if self._use_default_lock else self._lock return ( self._opener, self._args, self._mode, self._kwargs, lock, self._manager_id, ) def __setstate__(self, state) -> None: """Restore from a pickle.""" opener, args, mode, kwargs, lock, manager_id = state self.__init__( # type: ignore opener, *args, mode=mode, kwargs=kwargs, lock=lock, manager_id=manager_id ) def __repr__(self) -> str: args_string = ", ".join(map(repr, self._args)) if self._mode is not _DEFAULT_MODE: args_string += f", mode={self._mode!r}" return ( f"{type(self).__name__}({self._opener!r}, {args_string}, " f"kwargs={self._kwargs}, manager_id={self._manager_id!r})" ) class _RefCounter: """Class for keeping track of reference counts.""" def __init__(self, counts): self._counts = counts self._lock = threading.Lock() def increment(self, name): with self._lock: count = self._counts[name] = self._counts.get(name, 0) + 1 return count def decrement(self, name): with self._lock: count = self._counts[name] - 1 if count: self._counts[name] = count else: del self._counts[name] return count class _HashedSequence(list): """Speedup repeated look-ups by caching hash values. Based on what Python uses internally in functools.lru_cache. Python doesn't perform this optimization automatically: https://bugs.python.org/issue1462796 """ def __init__(self, tuple_value): self[:] = tuple_value self.hashvalue = hash(tuple_value) def __hash__(self): return self.hashvalue class DummyFileManager(FileManager): """FileManager that simply wraps an open file in the FileManager interface.""" def __init__(self, value): self._value = value def acquire(self, needs_lock=True): del needs_lock # ignored return self._value @contextlib.contextmanager def acquire_context(self, needs_lock=True): del needs_lock yield self._value def close(self, needs_lock=True): del needs_lock # ignored self._value.close()