Metadata-Version: 2.1 Name: cymem Version: 2.0.8 Summary: Manage calls to calloc/free through Cython Home-page: https://github.com/explosion/cymem Author: Matthew Honnibal Author-email: matt@explosion.ai License: MIT Classifier: Environment :: Console Classifier: Intended Audience :: Developers Classifier: Intended Audience :: Science/Research Classifier: License :: OSI Approved :: MIT License Classifier: Operating System :: POSIX :: Linux Classifier: Operating System :: MacOS :: MacOS X Classifier: Operating System :: Microsoft :: Windows Classifier: Programming Language :: Cython Classifier: Programming Language :: Python :: 2.6 Classifier: Programming Language :: Python :: 2.7 Classifier: Programming Language :: Python :: 3.3 Classifier: Programming Language :: Python :: 3.4 Classifier: Programming Language :: Python :: 3.5 Classifier: Programming Language :: Python :: 3.6 Classifier: Programming Language :: Python :: 3.7 Classifier: Programming Language :: Python :: 3.8 Classifier: Programming Language :: Python :: 3.9 Classifier: Programming Language :: Python :: 3.10 Classifier: Programming Language :: Python :: 3.11 Classifier: Programming Language :: Python :: 3.12 Classifier: Topic :: Scientific/Engineering Description-Content-Type: text/markdown License-File: LICENSE # cymem: A Cython Memory Helper cymem provides two small memory-management helpers for Cython. They make it easy to tie memory to a Python object's life-cycle, so that the memory is freed when the object is garbage collected. [![tests](https://github.com/explosion/cymem/actions/workflows/tests.yml/badge.svg)](https://github.com/explosion/cymem/actions/workflows/tests.yml) [![pypi Version](https://img.shields.io/pypi/v/cymem.svg?style=flat-square&logo=pypi&logoColor=white)](https://pypi.python.org/pypi/cymem) [![conda Version](https://img.shields.io/conda/vn/conda-forge/cymem.svg?style=flat-square&logo=conda-forge&logoColor=white)](https://anaconda.org/conda-forge/cymem) [![Python wheels](https://img.shields.io/badge/wheels-%E2%9C%93-4c1.svg?longCache=true&style=flat-square&logo=python&logoColor=white)](https://github.com/explosion/wheelwright/releases) ## Overview The most useful is `cymem.Pool`, which acts as a thin wrapper around the calloc function: ```python from cymem.cymem cimport Pool cdef Pool mem = Pool() data1 = mem.alloc(10, sizeof(int)) data2 = mem.alloc(12, sizeof(float)) ``` The `Pool` object saves the memory addresses internally, and frees them when the object is garbage collected. Typically you'll attach the `Pool` to some cdef'd class. This is particularly handy for deeply nested structs, which have complicated initialization functions. Just pass the `Pool` object into the initializer, and you don't have to worry about freeing your struct at all — all of the calls to `Pool.alloc` will be automatically freed when the `Pool` expires. ## Installation Installation is via [pip](https://pypi.python.org/pypi/pip), and requires [Cython](http://cython.org). Before installing, make sure that your `pip`, `setuptools` and `wheel` are up to date. ```bash pip install -U pip setuptools wheel pip install cymem ``` ## Example Use Case: An array of structs Let's say we want a sequence of sparse matrices. We need fast access, and a Python list isn't performing well enough. So, we want a C-array or C++ vector, which means we need the sparse matrix to be a C-level struct — it can't be a Python class. We can write this easily enough in Cython: ```python """Example without Cymem To use an array of structs, we must carefully walk the data structure when we deallocate it. """ from libc.stdlib cimport calloc, free cdef struct SparseRow: size_t length size_t* indices double* values cdef struct SparseMatrix: size_t length SparseRow* rows cdef class MatrixArray: cdef size_t length cdef SparseMatrix** matrices def __cinit__(self, list py_matrices): self.length = 0 self.matrices = NULL def __init__(self, list py_matrices): self.length = len(py_matrices) self.matrices = calloc(len(py_matrices), sizeof(SparseMatrix*)) for i, py_matrix in enumerate(py_matrices): self.matrices[i] = sparse_matrix_init(py_matrix) def __dealloc__(self): for i in range(self.length): sparse_matrix_free(self.matrices[i]) free(self.matrices) cdef SparseMatrix* sparse_matrix_init(list py_matrix) except NULL: sm = calloc(1, sizeof(SparseMatrix)) sm.length = len(py_matrix) sm.rows = calloc(sm.length, sizeof(SparseRow)) cdef size_t i, j cdef dict py_row cdef size_t idx cdef double value for i, py_row in enumerate(py_matrix): sm.rows[i].length = len(py_row) sm.rows[i].indices = calloc(sm.rows[i].length, sizeof(size_t)) sm.rows[i].values = calloc(sm.rows[i].length, sizeof(double)) for j, (idx, value) in enumerate(py_row.items()): sm.rows[i].indices[j] = idx sm.rows[i].values[j] = value return sm cdef void* sparse_matrix_free(SparseMatrix* sm) except *: cdef size_t i for i in range(sm.length): free(sm.rows[i].indices) free(sm.rows[i].values) free(sm.rows) free(sm) ``` We wrap the data structure in a Python ref-counted class at as low a level as we can, given our performance constraints. This allows us to allocate and free the memory in the `__cinit__` and `__dealloc__` Cython special methods. However, it's very easy to make mistakes when writing the `__dealloc__` and `sparse_matrix_free` functions, leading to memory leaks. cymem prevents you from writing these deallocators at all. Instead, you write as follows: ```python """Example with Cymem. Memory allocation is hidden behind the Pool class, which remembers the addresses it gives out. When the Pool object is garbage collected, all of its addresses are freed. We don't need to write MatrixArray.__dealloc__ or sparse_matrix_free, eliminating a common class of bugs. """ from cymem.cymem cimport Pool cdef struct SparseRow: size_t length size_t* indices double* values cdef struct SparseMatrix: size_t length SparseRow* rows cdef class MatrixArray: cdef size_t length cdef SparseMatrix** matrices cdef Pool mem def __cinit__(self, list py_matrices): self.mem = None self.length = 0 self.matrices = NULL def __init__(self, list py_matrices): self.mem = Pool() self.length = len(py_matrices) self.matrices = self.mem.alloc(self.length, sizeof(SparseMatrix*)) for i, py_matrix in enumerate(py_matrices): self.matrices[i] = sparse_matrix_init(self.mem, py_matrix) cdef SparseMatrix* sparse_matrix_init_cymem(Pool mem, list py_matrix) except NULL: sm = mem.alloc(1, sizeof(SparseMatrix)) sm.length = len(py_matrix) sm.rows = mem.alloc(sm.length, sizeof(SparseRow)) cdef size_t i, j cdef dict py_row cdef size_t idx cdef double value for i, py_row in enumerate(py_matrix): sm.rows[i].length = len(py_row) sm.rows[i].indices = mem.alloc(sm.rows[i].length, sizeof(size_t)) sm.rows[i].values = mem.alloc(sm.rows[i].length, sizeof(double)) for j, (idx, value) in enumerate(py_row.items()): sm.rows[i].indices[j] = idx sm.rows[i].values[j] = value return sm ``` All that the `Pool` class does is remember the addresses it gives out. When the `MatrixArray` object is garbage-collected, the `Pool` object will also be garbage collected, which triggers a call to `Pool.__dealloc__`. The `Pool` then frees all of its addresses. This saves you from walking back over your nested data structures to free them, eliminating a common class of errors. ## Custom Allocators Sometimes external C libraries use private functions to allocate and free objects, but we'd still like the laziness of the `Pool`. ```python from cymem.cymem cimport Pool, WrapMalloc, WrapFree cdef Pool mem = Pool(WrapMalloc(priv_malloc), WrapFree(priv_free)) ```