.. For doctests: >>> import sys >>> setup = getfixture('parallel_numpy_fixture') >>> fixture = setup(sys.modules[__name__]) Working with numerical data in shared memory (memmapping) ========================================================= By default the workers of the pool are real Python processes forked using the ``multiprocessing`` module of the Python standard library when ``n_jobs != 1``. The arguments passed as input to the ``Parallel`` call are serialized and reallocated in the memory of each worker process. This can be problematic for large arguments as they will be reallocated ``n_jobs`` times by the workers. As this problem can often occur in scientific computing with ``numpy`` based datastructures, :class:`joblib.Parallel` provides a special handling for large arrays to automatically dump them on the filesystem and pass a reference to the worker to open them as memory map on that file using the ``numpy.memmap`` subclass of ``numpy.ndarray``. This makes it possible to share a segment of data between all the worker processes. .. note:: The following only applies with the ``"loky"` and ``'multiprocessing'`` process-backends. If your code can release the GIL, then using a thread-based backend by passing ``prefer='threads'`` is even more efficient because it makes it possible to avoid the communication overhead of process-based parallelism. Scientific Python libraries such as numpy, scipy, pandas and scikit-learn often release the GIL in performance critical code paths. It is therefore advised to always measure the speed of thread-based parallelism and use it when the scalability is not limited by the GIL. Automated array to memmap conversion ------------------------------------ The automated array to memmap conversion is triggered by a configurable threshold on the size of the array:: >>> import numpy as np >>> from joblib import Parallel, delayed >>> def is_memmap(obj): ... return isinstance(obj, np.memmap) >>> Parallel(n_jobs=2, max_nbytes=1e6)( ... delayed(is_memmap)(np.ones(int(i))) ... for i in [1e2, 1e4, 1e6]) [False, False, True] By default the data is dumped to the ``/dev/shm`` shared-memory partition if it exists and is writable (typically the case under Linux). Otherwise the operating system's temporary folder is used. The location of the temporary data files can be customized by passing a ``temp_folder`` argument to the ``Parallel`` constructor. Passing ``max_nbytes=None`` makes it possible to disable the automated array to memmap conversion. Manual management of memmapped input data ----------------------------------------- For even finer tuning of the memory usage it is also possible to dump the array as a memmap directly from the parent process to free the memory before forking the worker processes. For instance let's allocate a large array in the memory of the parent process:: >>> large_array = np.ones(int(1e6)) Dump it to a local file for memmapping:: >>> import tempfile >>> import os >>> from joblib import load, dump >>> temp_folder = tempfile.mkdtemp() >>> filename = os.path.join(temp_folder, 'joblib_test.mmap') >>> if os.path.exists(filename): os.unlink(filename) >>> _ = dump(large_array, filename) >>> large_memmap = load(filename, mmap_mode='r+') The ``large_memmap`` variable is pointing to a ``numpy.memmap`` instance:: >>> large_memmap.__class__.__name__, large_array.nbytes, large_array.shape ('memmap', 8000000, (1000000,)) >>> np.allclose(large_array, large_memmap) True The original array can be freed from the main process memory:: >>> del large_array >>> import gc >>> _ = gc.collect() It is possible to slice ``large_memmap`` into a smaller memmap:: >>> small_memmap = large_memmap[2:5] >>> small_memmap.__class__.__name__, small_memmap.nbytes, small_memmap.shape ('memmap', 24, (3,)) Finally a ``np.ndarray`` view backed on that same memory mapped file can be used:: >>> small_array = np.asarray(small_memmap) >>> small_array.__class__.__name__, small_array.nbytes, small_array.shape ('ndarray', 24, (3,)) All those three datastructures point to the same memory buffer and this same buffer will also be reused directly by the worker processes of a ``Parallel`` call:: >>> Parallel(n_jobs=2, max_nbytes=None)( ... delayed(is_memmap)(a) ... for a in [large_memmap, small_memmap, small_array]) [True, True, True] Note that here ``max_nbytes=None`` is used to disable the auto-dumping feature of ``Parallel``. ``small_array`` is still in shared memory in the worker processes because it was already backed by shared memory in the parent process. The pickling machinery of ``Parallel`` multiprocessing queues are able to detect this situation and optimize it on the fly to limit the number of memory copies. Writing parallel computation results in shared memory ----------------------------------------------------- If data are opened using the ``w+`` or ``r+`` mode in the main program, the worker will get ``r+`` mode access. Thus the worker will be able to write its results directly to the original data, alleviating the need of the serialization to send back the results to the parent process. Here is an example script on parallel processing with preallocated ``numpy.memmap`` datastructures :ref:`sphx_glr_auto_examples_parallel_memmap.py`. .. warning:: Having concurrent workers write on overlapping shared memory data segments, for instance by using inplace operators and assignments on a `numpy.memmap` instance, can lead to data corruption as numpy does not offer atomic operations. The previous example does not risk that issue as each task is updating an exclusive segment of the shared result array. Some C/C++ compilers offer lock-free atomic primitives such as add-and-fetch or compare-and-swap that could be exposed to Python via CFFI_ for instance. However providing numpy-aware atomic constructs is outside of the scope of the joblib project. .. _CFFI: https://cffi.readthedocs.org A final note: don't forget to clean up any temporary folder when you are done with the computation:: >>> import shutil >>> try: ... shutil.rmtree(temp_folder) ... except OSError: ... pass # this can sometimes fail under Windows