upstream/mercurial-mirror Files · contrib/python-zstandard/c-ext/compressiondict.c

contrib: add a partial-merge tool for sorted lists (such as Python imports)...

contrib: add a partial-merge tool for sorted lists (such as Python imports) This is a pretty naive tool that uses a regular expression for matching lines. It is based on a Google-internal tool that worked in a similar way. For now, the regular expression is hard-coded to attempt to match single-line Python imports. The only commit I've found in the hg core repo where the tool helped was commit 9cd6292abfdf. I think that's because we often use multiple imports per import statement. I think this tool is still a decent first step (especially once the regex is made configurable in the next patch). The merging should ideally use a proper Python parser and do the merge at the AST (or CST?) level, but that's significantly harder, especially if you want to preserve comments and whitespace. It's also less generic. Differential Revision: https://phab.mercurial-scm.org/D12380

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      /**

      * Copyright (c) 2016-present, Gregory Szorc

      * All rights reserved.

      *

      * This software may be modified and distributed under the terms

      * of the BSD license. See the LICENSE file for details.

      */

      #include "python-zstandard.h"

      extern PyObject* ZstdError;

      ZstdCompressionDict* train_dictionary(PyObject* self, PyObject* args, PyObject* kwargs) {

      	static char* kwlist[] = {

      		"dict_size",

      		"samples",

      		"k",

      		"d",

      		"notifications",

      		"dict_id",

      		"level",

      		"steps",

      		"threads",

      		NULL

      	};

      	size_t capacity;

      	PyObject* samples;

      	unsigned k = 0;

      	unsigned d = 0;

      	unsigned notifications = 0;

      	unsigned dictID = 0;

      	int level = 0;

      	unsigned steps = 0;

      	int threads = 0;

      	ZDICT_cover_params_t params;

      	Py_ssize_t samplesLen;

      	Py_ssize_t i;

      	size_t samplesSize = 0;

      	void* sampleBuffer = NULL;

      	size_t* sampleSizes = NULL;

      	void* sampleOffset;

      	Py_ssize_t sampleSize;

      	void* dict = NULL;

      	size_t zresult;

      	ZstdCompressionDict* result = NULL;

      	if (!PyArg_ParseTupleAndKeywords(args, kwargs, "nO!|IIIIiIi:train_dictionary",

      		kwlist, &capacity, &PyList_Type, &samples,

      		&k, &d, &notifications, &dictID, &level, &steps, &threads)) {

      		return NULL;

      	}

      	if (threads < 0) {

      		threads = cpu_count();

      	}

      	memset(&params, 0, sizeof(params));

      	params.k = k;

      	params.d = d;

      	params.steps = steps;

      	params.nbThreads = threads;

      	params.zParams.notificationLevel = notifications;

      	params.zParams.dictID = dictID;

      	params.zParams.compressionLevel = level;

      	/* Figure out total size of input samples. */

      	samplesLen = PyList_Size(samples);

      	for (i = 0; i < samplesLen; i++) {

      		PyObject* sampleItem = PyList_GET_ITEM(samples, i);

      		if (!PyBytes_Check(sampleItem)) {

      			PyErr_SetString(PyExc_ValueError, "samples must be bytes");

      			return NULL;

      		}

      		samplesSize += PyBytes_GET_SIZE(sampleItem);

      	}

      	sampleBuffer = PyMem_Malloc(samplesSize);

      	if (!sampleBuffer) {

      		PyErr_NoMemory();

      		goto finally;

      	}

      	sampleSizes = PyMem_Malloc(samplesLen * sizeof(size_t));

      	if (!sampleSizes) {

      		PyErr_NoMemory();

      		goto finally;

      	}

      	sampleOffset = sampleBuffer;

      	for (i = 0; i < samplesLen; i++) {

      		PyObject* sampleItem = PyList_GET_ITEM(samples, i);

      		sampleSize = PyBytes_GET_SIZE(sampleItem);

      		sampleSizes[i] = sampleSize;

      		memcpy(sampleOffset, PyBytes_AS_STRING(sampleItem), sampleSize);

      		sampleOffset = (char*)sampleOffset + sampleSize;

      	}

      	dict = PyMem_Malloc(capacity);

      	if (!dict) {

      		PyErr_NoMemory();

      		goto finally;

      	}

      	Py_BEGIN_ALLOW_THREADS

      	/* No parameters uses the default function, which will use default params

      	   and call ZDICT_optimizeTrainFromBuffer_cover under the hood. */

      	if (!params.k && !params.d && !params.zParams.compressionLevel

      		&& !params.zParams.notificationLevel && !params.zParams.dictID) {

      		zresult = ZDICT_trainFromBuffer(dict, capacity, sampleBuffer,

      			sampleSizes, (unsigned)samplesLen);

      	}

      	/* Use optimize mode if user controlled steps or threads explicitly. */

      	else if (params.steps || params.nbThreads) {

      		zresult = ZDICT_optimizeTrainFromBuffer_cover(dict, capacity,

      			sampleBuffer, sampleSizes, (unsigned)samplesLen, &params);

      	}

      	/* Non-optimize mode with explicit control. */

      	else {

      		zresult = ZDICT_trainFromBuffer_cover(dict, capacity,

      			sampleBuffer, sampleSizes, (unsigned)samplesLen, params);

      	}

      	Py_END_ALLOW_THREADS

      	if (ZDICT_isError(zresult)) {

      		PyMem_Free(dict);

      		PyErr_Format(ZstdError, "cannot train dict: %s", ZDICT_getErrorName(zresult));

      		goto finally;

      	}

      	result = PyObject_New(ZstdCompressionDict, &ZstdCompressionDictType);

      	if (!result) {

      		PyMem_Free(dict);

      		goto finally;

      	}

      	result->dictData = dict;

      	result->dictSize = zresult;

      	result->dictType = ZSTD_dct_fullDict;

      	result->d = params.d;

      	result->k = params.k;

      	result->cdict = NULL;

      	result->ddict = NULL;

      finally:

      	PyMem_Free(sampleBuffer);

      	PyMem_Free(sampleSizes);

      	return result;

      }

      int ensure_ddict(ZstdCompressionDict* dict) {

      	if (dict->ddict) {

      		return 0;

      	}

      	Py_BEGIN_ALLOW_THREADS

      	dict->ddict = ZSTD_createDDict_advanced(dict->dictData, dict->dictSize,

      		ZSTD_dlm_byRef, dict->dictType, ZSTD_defaultCMem);

      	Py_END_ALLOW_THREADS

      	if (!dict->ddict) {

      		PyErr_SetString(ZstdError, "could not create decompression dict");

      		return 1;

      	}

      	return 0;

      }

      PyDoc_STRVAR(ZstdCompressionDict__doc__,

      "ZstdCompressionDict(data) - Represents a computed compression dictionary\n"

      "\n"

      "This type holds the results of a computed Zstandard compression dictionary.\n"

      "Instances are obtained by calling ``train_dictionary()`` or by passing\n"

      "bytes obtained from another source into the constructor.\n"

      );

      static int ZstdCompressionDict_init(ZstdCompressionDict* self, PyObject* args, PyObject* kwargs) {

      	static char* kwlist[] = {

      		"data",

      		"dict_type",

      		NULL

      	};

      	int result = -1;

      	Py_buffer source;

      	unsigned dictType = ZSTD_dct_auto;

      	self->dictData = NULL;

      	self->dictSize = 0;

      	self->cdict = NULL;

      	self->ddict = NULL;

      #if PY_MAJOR_VERSION >= 3

      	if (!PyArg_ParseTupleAndKeywords(args, kwargs, "y*|I:ZstdCompressionDict",

      #else

      	if (!PyArg_ParseTupleAndKeywords(args, kwargs, "s*|I:ZstdCompressionDict",

      #endif

      		kwlist, &source, &dictType)) {

      		return -1;

      	}

      	if (!PyBuffer_IsContiguous(&source, 'C') || source.ndim > 1) {

      		PyErr_SetString(PyExc_ValueError,

      			"data buffer should be contiguous and have at most one dimension");

      		goto finally;

      	}

      	if (dictType != ZSTD_dct_auto && dictType != ZSTD_dct_rawContent

      		&& dictType != ZSTD_dct_fullDict) {

      		PyErr_Format(PyExc_ValueError,

      			"invalid dictionary load mode: %d; must use DICT_TYPE_* constants",

      			dictType);

      		goto finally;

      	}

      	self->dictType = dictType;

      	self->dictData = PyMem_Malloc(source.len);

      	if (!self->dictData) {

      		PyErr_NoMemory();

      		goto finally;

      	}

      	memcpy(self->dictData, source.buf, source.len);

      	self->dictSize = source.len;

      	result = 0;

      finally:

      	PyBuffer_Release(&source);

      	return result;

      }

      static void ZstdCompressionDict_dealloc(ZstdCompressionDict* self) {

      	if (self->cdict) {

      		ZSTD_freeCDict(self->cdict);

      		self->cdict = NULL;

      	}

      	if (self->ddict) {

      		ZSTD_freeDDict(self->ddict);

      		self->ddict = NULL;

      	}

      	if (self->dictData) {

      		PyMem_Free(self->dictData);

      		self->dictData = NULL;

      	}

      	PyObject_Del(self);

      }

      PyDoc_STRVAR(ZstdCompressionDict_precompute_compress__doc__,

      "Precompute a dictionary so it can be used by multiple compressors.\n"

      );

      static PyObject* ZstdCompressionDict_precompute_compress(ZstdCompressionDict* self, PyObject* args, PyObject* kwargs) {

      	static char* kwlist[] = {

      		"level",

      		"compression_params",

      		NULL

      	};

      	int level = 0;

      	ZstdCompressionParametersObject* compressionParams = NULL;

      	ZSTD_compressionParameters cParams;

      	size_t zresult;

      	if (!PyArg_ParseTupleAndKeywords(args, kwargs, "|iO!:precompute_compress", kwlist,

      		&level, &ZstdCompressionParametersType, &compressionParams)) {

      		return NULL;

      	}

      	if (level && compressionParams) {

      		PyErr_SetString(PyExc_ValueError,

      			"must only specify one of level or compression_params");

      		return NULL;

      	}

      	if (!level && !compressionParams) {

      		PyErr_SetString(PyExc_ValueError,

      			"must specify one of level or compression_params");

      		return NULL;

      	}

      	if (self->cdict) {

      		zresult = ZSTD_freeCDict(self->cdict);

      		self->cdict = NULL;

      		if (ZSTD_isError(zresult)) {

      			PyErr_Format(ZstdError, "unable to free CDict: %s",

      				ZSTD_getErrorName(zresult));

      			return NULL;

      		}

      	}

      	if (level) {

      		cParams = ZSTD_getCParams(level, 0, self->dictSize);

      	}

      	else {

      		if (to_cparams(compressionParams, &cParams)) {

      			return NULL;

      		}

      	}

      	assert(!self->cdict);

      	self->cdict = ZSTD_createCDict_advanced(self->dictData, self->dictSize,

      		ZSTD_dlm_byRef, self->dictType, cParams, ZSTD_defaultCMem);

      	if (!self->cdict) {

      		PyErr_SetString(ZstdError, "unable to precompute dictionary");

      		return NULL;

      	}

      	Py_RETURN_NONE;

      }

      static PyObject* ZstdCompressionDict_dict_id(ZstdCompressionDict* self) {

      	unsigned dictID = ZDICT_getDictID(self->dictData, self->dictSize);

      	return PyLong_FromLong(dictID);

      }

      static PyObject* ZstdCompressionDict_as_bytes(ZstdCompressionDict* self) {

      	return PyBytes_FromStringAndSize(self->dictData, self->dictSize);

      }

      static PyMethodDef ZstdCompressionDict_methods[] = {

      	{ "dict_id", (PyCFunction)ZstdCompressionDict_dict_id, METH_NOARGS,

      	PyDoc_STR("dict_id() -- obtain the numeric dictionary ID") },

      	{ "as_bytes", (PyCFunction)ZstdCompressionDict_as_bytes, METH_NOARGS,

      	PyDoc_STR("as_bytes() -- obtain the raw bytes constituting the dictionary data") },

      	{ "precompute_compress", (PyCFunction)ZstdCompressionDict_precompute_compress,

      	METH_VARARGS | METH_KEYWORDS, ZstdCompressionDict_precompute_compress__doc__ },

      	{ NULL, NULL }

      };

      static PyMemberDef ZstdCompressionDict_members[] = {

      	{ "k", T_UINT, offsetof(ZstdCompressionDict, k), READONLY,

      	  "segment size" },

      	{ "d", T_UINT, offsetof(ZstdCompressionDict, d), READONLY,

      	  "dmer size" },

      	{ NULL }

      };

      static Py_ssize_t ZstdCompressionDict_length(ZstdCompressionDict* self) {

      	return self->dictSize;

      }

      static PySequenceMethods ZstdCompressionDict_sq = {

      	(lenfunc)ZstdCompressionDict_length, /* sq_length */

      	0,                                   /* sq_concat */

      	0,                                   /* sq_repeat */

      	0,                                   /* sq_item */

      	0,                                   /* sq_ass_item */

      	0,                                   /* sq_contains */

      	0,                                   /* sq_inplace_concat */

      	0                                    /* sq_inplace_repeat */

      };

      PyTypeObject ZstdCompressionDictType = {

      	PyVarObject_HEAD_INIT(NULL, 0)

      	"zstd.ZstdCompressionDict",     /* tp_name */

      	sizeof(ZstdCompressionDict),    /* tp_basicsize */

      	0,                              /* tp_itemsize */

      	(destructor)ZstdCompressionDict_dealloc, /* tp_dealloc */

      	0,                              /* tp_print */

      	0,                              /* tp_getattr */

      	0,                              /* tp_setattr */

      	0,                              /* tp_compare */

      	0,                              /* tp_repr */

      	0,                              /* tp_as_number */

      	&ZstdCompressionDict_sq,        /* tp_as_sequence */

      	0,                              /* tp_as_mapping */

      	0,                              /* tp_hash */

      	0,                              /* tp_call */

      	0,                              /* tp_str */

      	0,                              /* tp_getattro */

      	0,                              /* tp_setattro */

      	0,                              /* tp_as_buffer */

      	Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE, /* tp_flags */

      	ZstdCompressionDict__doc__,     /* tp_doc */

      	0,                              /* tp_traverse */

      	0,                              /* tp_clear */

      	0,                              /* tp_richcompare */

      	0,                              /* tp_weaklistoffset */

      	0,                              /* tp_iter */

      	0,                              /* tp_iternext */

      	ZstdCompressionDict_methods,    /* tp_methods */

      	ZstdCompressionDict_members,    /* tp_members */

      	0,                              /* tp_getset */

      	0,                              /* tp_base */

      	0,                              /* tp_dict */

      	0,                              /* tp_descr_get */

      	0,                              /* tp_descr_set */

      	0,                              /* tp_dictoffset */

      	(initproc)ZstdCompressionDict_init, /* tp_init */

      	0,                              /* tp_alloc */

      	PyType_GenericNew,              /* tp_new */

      };

      void compressiondict_module_init(PyObject* mod) {

      	Py_SET_TYPE(&ZstdCompressionDictType, &PyType_Type);

      	if (PyType_Ready(&ZstdCompressionDictType) < 0) {

      		return;

      	}

      	Py_INCREF((PyObject*)&ZstdCompressionDictType);

      	PyModule_AddObject(mod, "ZstdCompressionDict",

      		(PyObject*)&ZstdCompressionDictType);

      }

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				/**
				* Copyright (c) 2016-present, Gregory Szorc
				* All rights reserved.
				*
				* This software may be modified and distributed under the terms
				* of the BSD license. See the LICENSE file for details.
				*/

				#include "python-zstandard.h"

				extern PyObject* ZstdError;

				ZstdCompressionDict* train_dictionary(PyObject* self, PyObject* args, PyObject* kwargs) {
				static char* kwlist[] = {
				"dict_size",
				"samples",
				"k",
				"d",
				"notifications",
				"dict_id",
				"level",
				"steps",
				"threads",
				NULL
				};

				size_t capacity;
				PyObject* samples;
				unsigned k = 0;
				unsigned d = 0;
				unsigned notifications = 0;
				unsigned dictID = 0;
				int level = 0;
				unsigned steps = 0;
				int threads = 0;
				ZDICT_cover_params_t params;
				Py_ssize_t samplesLen;
				Py_ssize_t i;
				size_t samplesSize = 0;
				void* sampleBuffer = NULL;
				size_t* sampleSizes = NULL;
				void* sampleOffset;
				Py_ssize_t sampleSize;
				void* dict = NULL;
				size_t zresult;
				ZstdCompressionDict* result = NULL;

				if (!PyArg_ParseTupleAndKeywords(args, kwargs, "nO!\|IIIIiIi:train_dictionary",
				kwlist, &capacity, &PyList_Type, &samples,
				&k, &d, &notifications, &dictID, &level, &steps, &threads)) {
				return NULL;
				}

				if (threads < 0) {
				threads = cpu_count();
				}

				memset(&params, 0, sizeof(params));
				params.k = k;
				params.d = d;
				params.steps = steps;
				params.nbThreads = threads;
				params.zParams.notificationLevel = notifications;
				params.zParams.dictID = dictID;
				params.zParams.compressionLevel = level;

				/* Figure out total size of input samples. */
				samplesLen = PyList_Size(samples);
				for (i = 0; i < samplesLen; i++) {
				PyObject* sampleItem = PyList_GET_ITEM(samples, i);

				if (!PyBytes_Check(sampleItem)) {
				PyErr_SetString(PyExc_ValueError, "samples must be bytes");
				return NULL;
				}
				samplesSize += PyBytes_GET_SIZE(sampleItem);
				}

				sampleBuffer = PyMem_Malloc(samplesSize);
				if (!sampleBuffer) {
				PyErr_NoMemory();
				goto finally;
				}

				sampleSizes = PyMem_Malloc(samplesLen * sizeof(size_t));
				if (!sampleSizes) {
				PyErr_NoMemory();
				goto finally;
				}

				sampleOffset = sampleBuffer;
				for (i = 0; i < samplesLen; i++) {
				PyObject* sampleItem = PyList_GET_ITEM(samples, i);
				sampleSize = PyBytes_GET_SIZE(sampleItem);
				sampleSizes[i] = sampleSize;
				memcpy(sampleOffset, PyBytes_AS_STRING(sampleItem), sampleSize);
				sampleOffset = (char*)sampleOffset + sampleSize;
				}

				dict = PyMem_Malloc(capacity);
				if (!dict) {
				PyErr_NoMemory();
				goto finally;
				}

				Py_BEGIN_ALLOW_THREADS
				/* No parameters uses the default function, which will use default params
				and call ZDICT_optimizeTrainFromBuffer_cover under the hood. */
				if (!params.k && !params.d && !params.zParams.compressionLevel
				&& !params.zParams.notificationLevel && !params.zParams.dictID) {
				zresult = ZDICT_trainFromBuffer(dict, capacity, sampleBuffer,
				sampleSizes, (unsigned)samplesLen);
				}
				/* Use optimize mode if user controlled steps or threads explicitly. */
				else if (params.steps \|\| params.nbThreads) {
				zresult = ZDICT_optimizeTrainFromBuffer_cover(dict, capacity,
				sampleBuffer, sampleSizes, (unsigned)samplesLen, &params);
				}
				/* Non-optimize mode with explicit control. */
				else {
				zresult = ZDICT_trainFromBuffer_cover(dict, capacity,
				sampleBuffer, sampleSizes, (unsigned)samplesLen, params);
				}
				Py_END_ALLOW_THREADS

				if (ZDICT_isError(zresult)) {
				PyMem_Free(dict);
				PyErr_Format(ZstdError, "cannot train dict: %s", ZDICT_getErrorName(zresult));
				goto finally;
				}

				result = PyObject_New(ZstdCompressionDict, &ZstdCompressionDictType);
				if (!result) {
				PyMem_Free(dict);
				goto finally;
				}

				result->dictData = dict;
				result->dictSize = zresult;
				result->dictType = ZSTD_dct_fullDict;
				result->d = params.d;
				result->k = params.k;
				result->cdict = NULL;
				result->ddict = NULL;

				finally:
				PyMem_Free(sampleBuffer);
				PyMem_Free(sampleSizes);

				return result;
				}

				int ensure_ddict(ZstdCompressionDict* dict) {
				if (dict->ddict) {
				return 0;
				}

				Py_BEGIN_ALLOW_THREADS
				dict->ddict = ZSTD_createDDict_advanced(dict->dictData, dict->dictSize,
				ZSTD_dlm_byRef, dict->dictType, ZSTD_defaultCMem);
				Py_END_ALLOW_THREADS
				if (!dict->ddict) {
				PyErr_SetString(ZstdError, "could not create decompression dict");
				return 1;
				}

				return 0;
				}

				PyDoc_STRVAR(ZstdCompressionDict__doc__,
				"ZstdCompressionDict(data) - Represents a computed compression dictionary\n"
				"\n"
				"This type holds the results of a computed Zstandard compression dictionary.\n"
				"Instances are obtained by calling ``train_dictionary()`` or by passing\n"
				"bytes obtained from another source into the constructor.\n"
				);

				static int ZstdCompressionDict_init(ZstdCompressionDict* self, PyObject* args, PyObject* kwargs) {
				static char* kwlist[] = {
				"data",
				"dict_type",
				NULL
				};

				int result = -1;
				Py_buffer source;
				unsigned dictType = ZSTD_dct_auto;

				self->dictData = NULL;
				self->dictSize = 0;
				self->cdict = NULL;
				self->ddict = NULL;

				#if PY_MAJOR_VERSION >= 3
				if (!PyArg_ParseTupleAndKeywords(args, kwargs, "y*\|I:ZstdCompressionDict",
				#else
				if (!PyArg_ParseTupleAndKeywords(args, kwargs, "s*\|I:ZstdCompressionDict",
				#endif
				kwlist, &source, &dictType)) {
				return -1;
				}

				if (!PyBuffer_IsContiguous(&source, 'C') \|\| source.ndim > 1) {
				PyErr_SetString(PyExc_ValueError,
				"data buffer should be contiguous and have at most one dimension");
				goto finally;
				}

				if (dictType != ZSTD_dct_auto && dictType != ZSTD_dct_rawContent
				&& dictType != ZSTD_dct_fullDict) {
				PyErr_Format(PyExc_ValueError,
				"invalid dictionary load mode: %d; must use DICT_TYPE_* constants",
				dictType);
				goto finally;
				}

				self->dictType = dictType;

				self->dictData = PyMem_Malloc(source.len);
				if (!self->dictData) {
				PyErr_NoMemory();
				goto finally;
				}

				memcpy(self->dictData, source.buf, source.len);
				self->dictSize = source.len;

				result = 0;

				finally:
				PyBuffer_Release(&source);
				return result;
				}

				static void ZstdCompressionDict_dealloc(ZstdCompressionDict* self) {
				if (self->cdict) {
				ZSTD_freeCDict(self->cdict);
				self->cdict = NULL;
				}

				if (self->ddict) {
				ZSTD_freeDDict(self->ddict);
				self->ddict = NULL;
				}

				if (self->dictData) {
				PyMem_Free(self->dictData);
				self->dictData = NULL;
				}

				PyObject_Del(self);
				}

				PyDoc_STRVAR(ZstdCompressionDict_precompute_compress__doc__,
				"Precompute a dictionary so it can be used by multiple compressors.\n"
				);

				static PyObject* ZstdCompressionDict_precompute_compress(ZstdCompressionDict* self, PyObject* args, PyObject* kwargs) {
				static char* kwlist[] = {
				"level",
				"compression_params",
				NULL
				};

				int level = 0;
				ZstdCompressionParametersObject* compressionParams = NULL;
				ZSTD_compressionParameters cParams;
				size_t zresult;

				if (!PyArg_ParseTupleAndKeywords(args, kwargs, "\|iO!:precompute_compress", kwlist,
				&level, &ZstdCompressionParametersType, &compressionParams)) {
				return NULL;
				}

				if (level && compressionParams) {
				PyErr_SetString(PyExc_ValueError,
				"must only specify one of level or compression_params");
				return NULL;
				}

				if (!level && !compressionParams) {
				PyErr_SetString(PyExc_ValueError,
				"must specify one of level or compression_params");
				return NULL;
				}

				if (self->cdict) {
				zresult = ZSTD_freeCDict(self->cdict);
				self->cdict = NULL;
				if (ZSTD_isError(zresult)) {
				PyErr_Format(ZstdError, "unable to free CDict: %s",
				ZSTD_getErrorName(zresult));
				return NULL;
				}
				}

				if (level) {
				cParams = ZSTD_getCParams(level, 0, self->dictSize);
				}
				else {
				if (to_cparams(compressionParams, &cParams)) {
				return NULL;
				}
				}

				assert(!self->cdict);
				self->cdict = ZSTD_createCDict_advanced(self->dictData, self->dictSize,
				ZSTD_dlm_byRef, self->dictType, cParams, ZSTD_defaultCMem);

				if (!self->cdict) {
				PyErr_SetString(ZstdError, "unable to precompute dictionary");
				return NULL;
				}

				Py_RETURN_NONE;
				}

				static PyObject* ZstdCompressionDict_dict_id(ZstdCompressionDict* self) {
				unsigned dictID = ZDICT_getDictID(self->dictData, self->dictSize);

				return PyLong_FromLong(dictID);
				}

				static PyObject* ZstdCompressionDict_as_bytes(ZstdCompressionDict* self) {
				return PyBytes_FromStringAndSize(self->dictData, self->dictSize);
				}

				static PyMethodDef ZstdCompressionDict_methods[] = {
				{ "dict_id", (PyCFunction)ZstdCompressionDict_dict_id, METH_NOARGS,
				PyDoc_STR("dict_id() -- obtain the numeric dictionary ID") },
				{ "as_bytes", (PyCFunction)ZstdCompressionDict_as_bytes, METH_NOARGS,
				PyDoc_STR("as_bytes() -- obtain the raw bytes constituting the dictionary data") },
				{ "precompute_compress", (PyCFunction)ZstdCompressionDict_precompute_compress,
				METH_VARARGS \| METH_KEYWORDS, ZstdCompressionDict_precompute_compress__doc__ },
				{ NULL, NULL }
				};

				static PyMemberDef ZstdCompressionDict_members[] = {
				{ "k", T_UINT, offsetof(ZstdCompressionDict, k), READONLY,
				"segment size" },
				{ "d", T_UINT, offsetof(ZstdCompressionDict, d), READONLY,
				"dmer size" },
				{ NULL }
				};

				static Py_ssize_t ZstdCompressionDict_length(ZstdCompressionDict* self) {
				return self->dictSize;
				}

				static PySequenceMethods ZstdCompressionDict_sq = {
				(lenfunc)ZstdCompressionDict_length, /* sq_length */
				0, /* sq_concat */
				0, /* sq_repeat */
				0, /* sq_item */
				0, /* sq_ass_item */
				0, /* sq_contains */
				0, /* sq_inplace_concat */
				0 /* sq_inplace_repeat */
				};

				PyTypeObject ZstdCompressionDictType = {
				PyVarObject_HEAD_INIT(NULL, 0)
				"zstd.ZstdCompressionDict", /* tp_name */
				sizeof(ZstdCompressionDict), /* tp_basicsize */
				0, /* tp_itemsize */
				(destructor)ZstdCompressionDict_dealloc, /* tp_dealloc */
				0, /* tp_print */
				0, /* tp_getattr */
				0, /* tp_setattr */
				0, /* tp_compare */
				0, /* tp_repr */
				0, /* tp_as_number */
				&ZstdCompressionDict_sq, /* tp_as_sequence */
				0, /* tp_as_mapping */
				0, /* tp_hash */
				0, /* tp_call */
				0, /* tp_str */
				0, /* tp_getattro */
				0, /* tp_setattro */
				0, /* tp_as_buffer */
				Py_TPFLAGS_DEFAULT \| Py_TPFLAGS_BASETYPE, /* tp_flags */
				ZstdCompressionDict__doc__, /* tp_doc */
				0, /* tp_traverse */
				0, /* tp_clear */
				0, /* tp_richcompare */
				0, /* tp_weaklistoffset */
				0, /* tp_iter */
				0, /* tp_iternext */
				ZstdCompressionDict_methods, /* tp_methods */
				ZstdCompressionDict_members, /* tp_members */
				0, /* tp_getset */
				0, /* tp_base */
				0, /* tp_dict */
				0, /* tp_descr_get */
				0, /* tp_descr_set */
				0, /* tp_dictoffset */
				(initproc)ZstdCompressionDict_init, /* tp_init */
				0, /* tp_alloc */
				PyType_GenericNew, /* tp_new */
				};

				void compressiondict_module_init(PyObject* mod) {
				Py_SET_TYPE(&ZstdCompressionDictType, &PyType_Type);
				if (PyType_Ready(&ZstdCompressionDictType) < 0) {
				return;
				}

				Py_INCREF((PyObject*)&ZstdCompressionDictType);
				PyModule_AddObject(mod, "ZstdCompressionDict",
				(PyObject*)&ZstdCompressionDictType);
				}