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/* ******************************************************************
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 * FSE : Finite State Entropy codec
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 * Public Prototypes declaration
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 * Copyright (c) Yann Collet, Facebook, Inc.
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 *
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 * You can contact the author at :
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 * - Source repository : https://github.com/Cyan4973/FiniteStateEntropy
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 *
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 * This source code is licensed under both the BSD-style license (found in the
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 * LICENSE file in the root directory of this source tree) and the GPLv2 (found
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 * in the COPYING file in the root directory of this source tree).
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 * You may select, at your option, one of the above-listed licenses.
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****************************************************************** */
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#if defined (__cplusplus)
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extern "C" {
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#endif
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#ifndef FSE_H
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#define FSE_H
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/*-*****************************************
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*  Dependencies
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******************************************/
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#include "zstd_deps.h"    /* size_t, ptrdiff_t */
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/*-*****************************************
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*  FSE_PUBLIC_API : control library symbols visibility
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******************************************/
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#if defined(FSE_DLL_EXPORT) && (FSE_DLL_EXPORT==1) && defined(__GNUC__) && (__GNUC__ >= 4)
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#  define FSE_PUBLIC_API __attribute__ ((visibility ("default")))
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#elif defined(FSE_DLL_EXPORT) && (FSE_DLL_EXPORT==1)   /* Visual expected */
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#  define FSE_PUBLIC_API __declspec(dllexport)
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#elif defined(FSE_DLL_IMPORT) && (FSE_DLL_IMPORT==1)
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#  define FSE_PUBLIC_API __declspec(dllimport) /* It isn't required but allows to generate better code, saving a function pointer load from the IAT and an indirect jump.*/
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#else
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#  define FSE_PUBLIC_API
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#endif
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/*------   Version   ------*/
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#define FSE_VERSION_MAJOR    0
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#define FSE_VERSION_MINOR    9
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#define FSE_VERSION_RELEASE  0
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#define FSE_LIB_VERSION FSE_VERSION_MAJOR.FSE_VERSION_MINOR.FSE_VERSION_RELEASE
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#define FSE_QUOTE(str) #str
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#define FSE_EXPAND_AND_QUOTE(str) FSE_QUOTE(str)
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#define FSE_VERSION_STRING FSE_EXPAND_AND_QUOTE(FSE_LIB_VERSION)
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#define FSE_VERSION_NUMBER  (FSE_VERSION_MAJOR *100*100 + FSE_VERSION_MINOR *100 + FSE_VERSION_RELEASE)
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FSE_PUBLIC_API unsigned FSE_versionNumber(void);   /**< library version number; to be used when checking dll version */
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/*-****************************************
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*  FSE simple functions
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******************************************/
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/*! FSE_compress() :
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    Compress content of buffer 'src', of size 'srcSize', into destination buffer 'dst'.
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    'dst' buffer must be already allocated. Compression runs faster is dstCapacity >= FSE_compressBound(srcSize).
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    @return : size of compressed data (<= dstCapacity).
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    Special values : if return == 0, srcData is not compressible => Nothing is stored within dst !!!
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                     if return == 1, srcData is a single byte symbol * srcSize times. Use RLE compression instead.
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                     if FSE_isError(return), compression failed (more details using FSE_getErrorName())
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*/
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FSE_PUBLIC_API size_t FSE_compress(void* dst, size_t dstCapacity,
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                             const void* src, size_t srcSize);
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/*! FSE_decompress():
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    Decompress FSE data from buffer 'cSrc', of size 'cSrcSize',
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    into already allocated destination buffer 'dst', of size 'dstCapacity'.
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    @return : size of regenerated data (<= maxDstSize),
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              or an error code, which can be tested using FSE_isError() .
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    ** Important ** : FSE_decompress() does not decompress non-compressible nor RLE data !!!
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    Why ? : making this distinction requires a header.
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    Header management is intentionally delegated to the user layer, which can better manage special cases.
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*/
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FSE_PUBLIC_API size_t FSE_decompress(void* dst,  size_t dstCapacity,
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                               const void* cSrc, size_t cSrcSize);
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/*-*****************************************
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*  Tool functions
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******************************************/
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FSE_PUBLIC_API size_t FSE_compressBound(size_t size);       /* maximum compressed size */
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/* Error Management */
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FSE_PUBLIC_API unsigned    FSE_isError(size_t code);        /* tells if a return value is an error code */
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FSE_PUBLIC_API const char* FSE_getErrorName(size_t code);   /* provides error code string (useful for debugging) */
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/*-*****************************************
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*  FSE advanced functions
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******************************************/
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/*! FSE_compress2() :
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    Same as FSE_compress(), but allows the selection of 'maxSymbolValue' and 'tableLog'
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    Both parameters can be defined as '0' to mean : use default value
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    @return : size of compressed data
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    Special values : if return == 0, srcData is not compressible => Nothing is stored within cSrc !!!
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                     if return == 1, srcData is a single byte symbol * srcSize times. Use RLE compression.
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                     if FSE_isError(return), it's an error code.
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*/
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FSE_PUBLIC_API size_t FSE_compress2 (void* dst, size_t dstSize, const void* src, size_t srcSize, unsigned maxSymbolValue, unsigned tableLog);
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/*-*****************************************
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*  FSE detailed API
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******************************************/
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/*!
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FSE_compress() does the following:
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1. count symbol occurrence from source[] into table count[] (see hist.h)
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2. normalize counters so that sum(count[]) == Power_of_2 (2^tableLog)
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3. save normalized counters to memory buffer using writeNCount()
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4. build encoding table 'CTable' from normalized counters
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5. encode the data stream using encoding table 'CTable'
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FSE_decompress() does the following:
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1. read normalized counters with readNCount()
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2. build decoding table 'DTable' from normalized counters
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3. decode the data stream using decoding table 'DTable'
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The following API allows targeting specific sub-functions for advanced tasks.
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For example, it's possible to compress several blocks using the same 'CTable',
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or to save and provide normalized distribution using external method.
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*/
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/* *** COMPRESSION *** */
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/*! FSE_optimalTableLog():
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    dynamically downsize 'tableLog' when conditions are met.
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    It saves CPU time, by using smaller tables, while preserving or even improving compression ratio.
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    @return : recommended tableLog (necessarily <= 'maxTableLog') */
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FSE_PUBLIC_API unsigned FSE_optimalTableLog(unsigned maxTableLog, size_t srcSize, unsigned maxSymbolValue);
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/*! FSE_normalizeCount():
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    normalize counts so that sum(count[]) == Power_of_2 (2^tableLog)
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    'normalizedCounter' is a table of short, of minimum size (maxSymbolValue+1).
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    useLowProbCount is a boolean parameter which trades off compressed size for
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    faster header decoding. When it is set to 1, the compressed data will be slightly
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    smaller. And when it is set to 0, FSE_readNCount() and FSE_buildDTable() will be
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    faster. If you are compressing a small amount of data (< 2 KB) then useLowProbCount=0
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    is a good default, since header deserialization makes a big speed difference.
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    Otherwise, useLowProbCount=1 is a good default, since the speed difference is small.
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    @return : tableLog,
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              or an errorCode, which can be tested using FSE_isError() */
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FSE_PUBLIC_API size_t FSE_normalizeCount(short* normalizedCounter, unsigned tableLog,
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                    const unsigned* count, size_t srcSize, unsigned maxSymbolValue, unsigned useLowProbCount);
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/*! FSE_NCountWriteBound():
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    Provides the maximum possible size of an FSE normalized table, given 'maxSymbolValue' and 'tableLog'.
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    Typically useful for allocation purpose. */
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FSE_PUBLIC_API size_t FSE_NCountWriteBound(unsigned maxSymbolValue, unsigned tableLog);
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/*! FSE_writeNCount():
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    Compactly save 'normalizedCounter' into 'buffer'.
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    @return : size of the compressed table,
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              or an errorCode, which can be tested using FSE_isError(). */
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FSE_PUBLIC_API size_t FSE_writeNCount (void* buffer, size_t bufferSize,
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                                 const short* normalizedCounter,
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                                 unsigned maxSymbolValue, unsigned tableLog);
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/*! Constructor and Destructor of FSE_CTable.
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    Note that FSE_CTable size depends on 'tableLog' and 'maxSymbolValue' */
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typedef unsigned FSE_CTable;   /* don't allocate that. It's only meant to be more restrictive than void* */
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FSE_PUBLIC_API FSE_CTable* FSE_createCTable (unsigned maxSymbolValue, unsigned tableLog);
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FSE_PUBLIC_API void        FSE_freeCTable (FSE_CTable* ct);
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/*! FSE_buildCTable():
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    Builds `ct`, which must be already allocated, using FSE_createCTable().
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    @return : 0, or an errorCode, which can be tested using FSE_isError() */
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FSE_PUBLIC_API size_t FSE_buildCTable(FSE_CTable* ct, const short* normalizedCounter, unsigned maxSymbolValue, unsigned tableLog);
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/*! FSE_compress_usingCTable():
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    Compress `src` using `ct` into `dst` which must be already allocated.
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    @return : size of compressed data (<= `dstCapacity`),
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              or 0 if compressed data could not fit into `dst`,
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              or an errorCode, which can be tested using FSE_isError() */
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FSE_PUBLIC_API size_t FSE_compress_usingCTable (void* dst, size_t dstCapacity, const void* src, size_t srcSize, const FSE_CTable* ct);
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/*!
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Tutorial :
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----------
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The first step is to count all symbols. FSE_count() does this job very fast.
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Result will be saved into 'count', a table of unsigned int, which must be already allocated, and have 'maxSymbolValuePtr[0]+1' cells.
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'src' is a table of bytes of size 'srcSize'. All values within 'src' MUST be <= maxSymbolValuePtr[0]
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maxSymbolValuePtr[0] will be updated, with its real value (necessarily <= original value)
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FSE_count() will return the number of occurrence of the most frequent symbol.
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This can be used to know if there is a single symbol within 'src', and to quickly evaluate its compressibility.
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If there is an error, the function will return an ErrorCode (which can be tested using FSE_isError()).
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The next step is to normalize the frequencies.
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FSE_normalizeCount() will ensure that sum of frequencies is == 2 ^'tableLog'.
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It also guarantees a minimum of 1 to any Symbol with frequency >= 1.
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You can use 'tableLog'==0 to mean "use default tableLog value".
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If you are unsure of which tableLog value to use, you can ask FSE_optimalTableLog(),
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which will provide the optimal valid tableLog given sourceSize, maxSymbolValue, and a user-defined maximum (0 means "default").
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The result of FSE_normalizeCount() will be saved into a table,
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called 'normalizedCounter', which is a table of signed short.
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'normalizedCounter' must be already allocated, and have at least 'maxSymbolValue+1' cells.
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The return value is tableLog if everything proceeded as expected.
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It is 0 if there is a single symbol within distribution.
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If there is an error (ex: invalid tableLog value), the function will return an ErrorCode (which can be tested using FSE_isError()).
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'normalizedCounter' can be saved in a compact manner to a memory area using FSE_writeNCount().
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'buffer' must be already allocated.
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For guaranteed success, buffer size must be at least FSE_headerBound().
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The result of the function is the number of bytes written into 'buffer'.
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If there is an error, the function will return an ErrorCode (which can be tested using FSE_isError(); ex : buffer size too small).
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'normalizedCounter' can then be used to create the compression table 'CTable'.
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The space required by 'CTable' must be already allocated, using FSE_createCTable().
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You can then use FSE_buildCTable() to fill 'CTable'.
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If there is an error, both functions will return an ErrorCode (which can be tested using FSE_isError()).
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'CTable' can then be used to compress 'src', with FSE_compress_usingCTable().
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Similar to FSE_count(), the convention is that 'src' is assumed to be a table of char of size 'srcSize'
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The function returns the size of compressed data (without header), necessarily <= `dstCapacity`.
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If it returns '0', compressed data could not fit into 'dst'.
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If there is an error, the function will return an ErrorCode (which can be tested using FSE_isError()).
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*/
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/* *** DECOMPRESSION *** */
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/*! FSE_readNCount():
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    Read compactly saved 'normalizedCounter' from 'rBuffer'.
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    @return : size read from 'rBuffer',
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              or an errorCode, which can be tested using FSE_isError().
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              maxSymbolValuePtr[0] and tableLogPtr[0] will also be updated with their respective values */
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FSE_PUBLIC_API size_t FSE_readNCount (short* normalizedCounter,
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                           unsigned* maxSymbolValuePtr, unsigned* tableLogPtr,
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                           const void* rBuffer, size_t rBuffSize);
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/*! FSE_readNCount_bmi2():
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 * Same as FSE_readNCount() but pass bmi2=1 when your CPU supports BMI2 and 0 otherwise.
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 */
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FSE_PUBLIC_API size_t FSE_readNCount_bmi2(short* normalizedCounter,
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                           unsigned* maxSymbolValuePtr, unsigned* tableLogPtr,
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                           const void* rBuffer, size_t rBuffSize, int bmi2);
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/*! Constructor and Destructor of FSE_DTable.
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    Note that its size depends on 'tableLog' */
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typedef unsigned FSE_DTable;   /* don't allocate that. It's just a way to be more restrictive than void* */
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FSE_PUBLIC_API FSE_DTable* FSE_createDTable(unsigned tableLog);
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FSE_PUBLIC_API void        FSE_freeDTable(FSE_DTable* dt);
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/*! FSE_buildDTable():
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    Builds 'dt', which must be already allocated, using FSE_createDTable().
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    return : 0, or an errorCode, which can be tested using FSE_isError() */
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FSE_PUBLIC_API size_t FSE_buildDTable (FSE_DTable* dt, const short* normalizedCounter, unsigned maxSymbolValue, unsigned tableLog);
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/*! FSE_decompress_usingDTable():
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    Decompress compressed source `cSrc` of size `cSrcSize` using `dt`
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    into `dst` which must be already allocated.
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    @return : size of regenerated data (necessarily <= `dstCapacity`),
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              or an errorCode, which can be tested using FSE_isError() */
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FSE_PUBLIC_API size_t FSE_decompress_usingDTable(void* dst, size_t dstCapacity, const void* cSrc, size_t cSrcSize, const FSE_DTable* dt);
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/*!
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Tutorial :
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----------
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(Note : these functions only decompress FSE-compressed blocks.
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 If block is uncompressed, use memcpy() instead
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 If block is a single repeated byte, use memset() instead )
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The first step is to obtain the normalized frequencies of symbols.
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This can be performed by FSE_readNCount() if it was saved using FSE_writeNCount().
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'normalizedCounter' must be already allocated, and have at least 'maxSymbolValuePtr[0]+1' cells of signed short.
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In practice, that means it's necessary to know 'maxSymbolValue' beforehand,
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or size the table to handle worst case situations (typically 256).
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FSE_readNCount() will provide 'tableLog' and 'maxSymbolValue'.
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The result of FSE_readNCount() is the number of bytes read from 'rBuffer'.
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Note that 'rBufferSize' must be at least 4 bytes, even if useful information is less than that.
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If there is an error, the function will return an error code, which can be tested using FSE_isError().
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The next step is to build the decompression tables 'FSE_DTable' from 'normalizedCounter'.
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This is performed by the function FSE_buildDTable().
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The space required by 'FSE_DTable' must be already allocated using FSE_createDTable().
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If there is an error, the function will return an error code, which can be tested using FSE_isError().
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`FSE_DTable` can then be used to decompress `cSrc`, with FSE_decompress_usingDTable().
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`cSrcSize` must be strictly correct, otherwise decompression will fail.
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FSE_decompress_usingDTable() result will tell how many bytes were regenerated (<=`dstCapacity`).
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If there is an error, the function will return an error code, which can be tested using FSE_isError(). (ex: dst buffer too small)
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*/
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#endif  /* FSE_H */
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#if defined(FSE_STATIC_LINKING_ONLY) && !defined(FSE_H_FSE_STATIC_LINKING_ONLY)
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#define FSE_H_FSE_STATIC_LINKING_ONLY
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/* *** Dependency *** */
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#include "bitstream.h"
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/* *****************************************
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*  Static allocation
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*******************************************/
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/* FSE buffer bounds */
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#define FSE_NCOUNTBOUND 512
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#define FSE_BLOCKBOUND(size) ((size) + ((size)>>7) + 4 /* fse states */ + sizeof(size_t) /* bitContainer */)
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#define FSE_COMPRESSBOUND(size) (FSE_NCOUNTBOUND + FSE_BLOCKBOUND(size))   /* Macro version, useful for static allocation */
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/* It is possible to statically allocate FSE CTable/DTable as a table of FSE_CTable/FSE_DTable using below macros */
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#define FSE_CTABLE_SIZE_U32(maxTableLog, maxSymbolValue)   (1 + (1<<((maxTableLog)-1)) + (((maxSymbolValue)+1)*2))
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#define FSE_DTABLE_SIZE_U32(maxTableLog)                   (1 + (1<<(maxTableLog)))
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/* or use the size to malloc() space directly. Pay attention to alignment restrictions though */
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#define FSE_CTABLE_SIZE(maxTableLog, maxSymbolValue)   (FSE_CTABLE_SIZE_U32(maxTableLog, maxSymbolValue) * sizeof(FSE_CTable))
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#define FSE_DTABLE_SIZE(maxTableLog)                   (FSE_DTABLE_SIZE_U32(maxTableLog) * sizeof(FSE_DTable))
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/* *****************************************
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 *  FSE advanced API
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 ***************************************** */
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unsigned FSE_optimalTableLog_internal(unsigned maxTableLog, size_t srcSize, unsigned maxSymbolValue, unsigned minus);
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/**< same as FSE_optimalTableLog(), which used `minus==2` */
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/* FSE_compress_wksp() :
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 * Same as FSE_compress2(), but using an externally allocated scratch buffer (`workSpace`).
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 * FSE_COMPRESS_WKSP_SIZE_U32() provides the minimum size required for `workSpace` as a table of FSE_CTable.
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 */
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#define FSE_COMPRESS_WKSP_SIZE_U32(maxTableLog, maxSymbolValue)   ( FSE_CTABLE_SIZE_U32(maxTableLog, maxSymbolValue) + ((maxTableLog > 12) ? (1 << (maxTableLog - 2)) : 1024) )
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size_t FSE_compress_wksp (void* dst, size_t dstSize, const void* src, size_t srcSize, unsigned maxSymbolValue, unsigned tableLog, void* workSpace, size_t wkspSize);
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size_t FSE_buildCTable_raw (FSE_CTable* ct, unsigned nbBits);
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/**< build a fake FSE_CTable, designed for a flat distribution, where each symbol uses nbBits */
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size_t FSE_buildCTable_rle (FSE_CTable* ct, unsigned char symbolValue);
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/**< build a fake FSE_CTable, designed to compress always the same symbolValue */
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/* FSE_buildCTable_wksp() :
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 * Same as FSE_buildCTable(), but using an externally allocated scratch buffer (`workSpace`).
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 * `wkspSize` must be >= `FSE_BUILD_CTABLE_WORKSPACE_SIZE_U32(maxSymbolValue, tableLog)` of `unsigned`.
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 * See FSE_buildCTable_wksp() for breakdown of workspace usage.
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 */
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#define FSE_BUILD_CTABLE_WORKSPACE_SIZE_U32(maxSymbolValue, tableLog) (((maxSymbolValue + 2) + (1ull << (tableLog)))/2 + sizeof(U64)/sizeof(U32) /* additional 8 bytes for potential table overwrite */)
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#define FSE_BUILD_CTABLE_WORKSPACE_SIZE(maxSymbolValue, tableLog) (sizeof(unsigned) * FSE_BUILD_CTABLE_WORKSPACE_SIZE_U32(maxSymbolValue, tableLog))
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size_t FSE_buildCTable_wksp(FSE_CTable* ct, const short* normalizedCounter, unsigned maxSymbolValue, unsigned tableLog, void* workSpace, size_t wkspSize);
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#define FSE_BUILD_DTABLE_WKSP_SIZE(maxTableLog, maxSymbolValue) (sizeof(short) * (maxSymbolValue + 1) + (1ULL << maxTableLog) + 8)
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#define FSE_BUILD_DTABLE_WKSP_SIZE_U32(maxTableLog, maxSymbolValue) ((FSE_BUILD_DTABLE_WKSP_SIZE(maxTableLog, maxSymbolValue) + sizeof(unsigned) - 1) / sizeof(unsigned))
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FSE_PUBLIC_API size_t FSE_buildDTable_wksp(FSE_DTable* dt, const short* normalizedCounter, unsigned maxSymbolValue, unsigned tableLog, void* workSpace, size_t wkspSize);
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/**< Same as FSE_buildDTable(), using an externally allocated `workspace` produced with `FSE_BUILD_DTABLE_WKSP_SIZE_U32(maxSymbolValue)` */
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size_t FSE_buildDTable_raw (FSE_DTable* dt, unsigned nbBits);
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/**< build a fake FSE_DTable, designed to read a flat distribution where each symbol uses nbBits */
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size_t FSE_buildDTable_rle (FSE_DTable* dt, unsigned char symbolValue);
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/**< build a fake FSE_DTable, designed to always generate the same symbolValue */
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#define FSE_DECOMPRESS_WKSP_SIZE_U32(maxTableLog, maxSymbolValue) (FSE_DTABLE_SIZE_U32(maxTableLog) + FSE_BUILD_DTABLE_WKSP_SIZE_U32(maxTableLog, maxSymbolValue) + (FSE_MAX_SYMBOL_VALUE + 1) / 2 + 1)
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#define FSE_DECOMPRESS_WKSP_SIZE(maxTableLog, maxSymbolValue) (FSE_DECOMPRESS_WKSP_SIZE_U32(maxTableLog, maxSymbolValue) * sizeof(unsigned))
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size_t FSE_decompress_wksp(void* dst, size_t dstCapacity, const void* cSrc, size_t cSrcSize, unsigned maxLog, void* workSpace, size_t wkspSize);
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/**< same as FSE_decompress(), using an externally allocated `workSpace` produced with `FSE_DECOMPRESS_WKSP_SIZE_U32(maxLog, maxSymbolValue)` */
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size_t FSE_decompress_wksp_bmi2(void* dst, size_t dstCapacity, const void* cSrc, size_t cSrcSize, unsigned maxLog, void* workSpace, size_t wkspSize, int bmi2);
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/**< Same as FSE_decompress_wksp() but with dynamic BMI2 support. Pass 1 if your CPU supports BMI2 or 0 if it doesn't. */
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typedef enum {
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   FSE_repeat_none,  /**< Cannot use the previous table */
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   FSE_repeat_check, /**< Can use the previous table but it must be checked */
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   FSE_repeat_valid  /**< Can use the previous table and it is assumed to be valid */
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 } FSE_repeat;
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/* *****************************************
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*  FSE symbol compression API
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*******************************************/
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/*!
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   This API consists of small unitary functions, which highly benefit from being inlined.
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   Hence their body are included in next section.
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*/
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typedef struct {
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    ptrdiff_t   value;
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    const void* stateTable;
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    const void* symbolTT;
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    unsigned    stateLog;
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} FSE_CState_t;
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static void FSE_initCState(FSE_CState_t* CStatePtr, const FSE_CTable* ct);
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static void FSE_encodeSymbol(BIT_CStream_t* bitC, FSE_CState_t* CStatePtr, unsigned symbol);
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static void FSE_flushCState(BIT_CStream_t* bitC, const FSE_CState_t* CStatePtr);
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/**<
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These functions are inner components of FSE_compress_usingCTable().
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They allow the creation of custom streams, mixing multiple tables and bit sources.
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A key property to keep in mind is that encoding and decoding are done **in reverse direction**.
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So the first symbol you will encode is the last you will decode, like a LIFO stack.
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You will need a few variables to track your CStream. They are :
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FSE_CTable    ct;         // Provided by FSE_buildCTable()
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BIT_CStream_t bitStream;  // bitStream tracking structure
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FSE_CState_t  state;      // State tracking structure (can have several)
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The first thing to do is to init bitStream and state.
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    size_t errorCode = BIT_initCStream(&bitStream, dstBuffer, maxDstSize);
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    FSE_initCState(&state, ct);
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Note that BIT_initCStream() can produce an error code, so its result should be tested, using FSE_isError();
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You can then encode your input data, byte after byte.
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FSE_encodeSymbol() outputs a maximum of 'tableLog' bits at a time.
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Remember decoding will be done in reverse direction.
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    FSE_encodeByte(&bitStream, &state, symbol);
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At any time, you can also add any bit sequence.
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Note : maximum allowed nbBits is 25, for compatibility with 32-bits decoders
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    BIT_addBits(&bitStream, bitField, nbBits);
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The above methods don't commit data to memory, they just store it into local register, for speed.
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Local register size is 64-bits on 64-bits systems, 32-bits on 32-bits systems (size_t).
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Writing data to memory is a manual operation, performed by the flushBits function.
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    BIT_flushBits(&bitStream);
422

423
Your last FSE encoding operation shall be to flush your last state value(s).
424
    FSE_flushState(&bitStream, &state);
425

426
Finally, you must close the bitStream.
427
The function returns the size of CStream in bytes.
428
If data couldn't fit into dstBuffer, it will return a 0 ( == not compressible)
429
If there is an error, it returns an errorCode (which can be tested using FSE_isError()).
430
    size_t size = BIT_closeCStream(&bitStream);
431
*/
432

433

434
/* *****************************************
435
*  FSE symbol decompression API
436
*******************************************/
437
typedef struct {
438
    size_t      state;
439
    const void* table;   /* precise table may vary, depending on U16 */
440
} FSE_DState_t;
441

442

443
static void     FSE_initDState(FSE_DState_t* DStatePtr, BIT_DStream_t* bitD, const FSE_DTable* dt);
444

445
static unsigned char FSE_decodeSymbol(FSE_DState_t* DStatePtr, BIT_DStream_t* bitD);
446

447
static unsigned FSE_endOfDState(const FSE_DState_t* DStatePtr);
448

449
/**<
450
Let's now decompose FSE_decompress_usingDTable() into its unitary components.
451
You will decode FSE-encoded symbols from the bitStream,
452
and also any other bitFields you put in, **in reverse order**.
453

454
You will need a few variables to track your bitStream. They are :
455

456
BIT_DStream_t DStream;    // Stream context
457
FSE_DState_t  DState;     // State context. Multiple ones are possible
458
FSE_DTable*   DTablePtr;  // Decoding table, provided by FSE_buildDTable()
459

460
The first thing to do is to init the bitStream.
461
    errorCode = BIT_initDStream(&DStream, srcBuffer, srcSize);
462

463
You should then retrieve your initial state(s)
464
(in reverse flushing order if you have several ones) :
465
    errorCode = FSE_initDState(&DState, &DStream, DTablePtr);
466

467
You can then decode your data, symbol after symbol.
468
For information the maximum number of bits read by FSE_decodeSymbol() is 'tableLog'.
469
Keep in mind that symbols are decoded in reverse order, like a LIFO stack (last in, first out).
470
    unsigned char symbol = FSE_decodeSymbol(&DState, &DStream);
471

472
You can retrieve any bitfield you eventually stored into the bitStream (in reverse order)
473
Note : maximum allowed nbBits is 25, for 32-bits compatibility
474
    size_t bitField = BIT_readBits(&DStream, nbBits);
475

476
All above operations only read from local register (which size depends on size_t).
477
Refueling the register from memory is manually performed by the reload method.
478
    endSignal = FSE_reloadDStream(&DStream);
479

480
BIT_reloadDStream() result tells if there is still some more data to read from DStream.
481
BIT_DStream_unfinished : there is still some data left into the DStream.
482
BIT_DStream_endOfBuffer : Dstream reached end of buffer. Its container may no longer be completely filled.
483
BIT_DStream_completed : Dstream reached its exact end, corresponding in general to decompression completed.
484
BIT_DStream_tooFar : Dstream went too far. Decompression result is corrupted.
485

486
When reaching end of buffer (BIT_DStream_endOfBuffer), progress slowly, notably if you decode multiple symbols per loop,
487
to properly detect the exact end of stream.
488
After each decoded symbol, check if DStream is fully consumed using this simple test :
489
    BIT_reloadDStream(&DStream) >= BIT_DStream_completed
490

491
When it's done, verify decompression is fully completed, by checking both DStream and the relevant states.
492
Checking if DStream has reached its end is performed by :
493
    BIT_endOfDStream(&DStream);
494
Check also the states. There might be some symbols left there, if some high probability ones (>50%) are possible.
495
    FSE_endOfDState(&DState);
496
*/
497

498

499
/* *****************************************
500
*  FSE unsafe API
501
*******************************************/
502
static unsigned char FSE_decodeSymbolFast(FSE_DState_t* DStatePtr, BIT_DStream_t* bitD);
503
/* faster, but works only if nbBits is always >= 1 (otherwise, result will be corrupted) */
504

505

506
/* *****************************************
507
*  Implementation of inlined functions
508
*******************************************/
509
typedef struct {
510
    int deltaFindState;
511
    U32 deltaNbBits;
512
} FSE_symbolCompressionTransform; /* total 8 bytes */
513

514
MEM_STATIC void FSE_initCState(FSE_CState_t* statePtr, const FSE_CTable* ct)
515
{
516
    const void* ptr = ct;
517
    const U16* u16ptr = (const U16*) ptr;
518
    const U32 tableLog = MEM_read16(ptr);
519
    statePtr->value = (ptrdiff_t)1<<tableLog;
520
    statePtr->stateTable = u16ptr+2;
521
    statePtr->symbolTT = ct + 1 + (tableLog ? (1<<(tableLog-1)) : 1);
522
    statePtr->stateLog = tableLog;
523
}
524

525

526
/*! FSE_initCState2() :
527
*   Same as FSE_initCState(), but the first symbol to include (which will be the last to be read)
528
*   uses the smallest state value possible, saving the cost of this symbol */
529
MEM_STATIC void FSE_initCState2(FSE_CState_t* statePtr, const FSE_CTable* ct, U32 symbol)
530
{
531
    FSE_initCState(statePtr, ct);
532
    {   const FSE_symbolCompressionTransform symbolTT = ((const FSE_symbolCompressionTransform*)(statePtr->symbolTT))[symbol];
533
        const U16* stateTable = (const U16*)(statePtr->stateTable);
534
        U32 nbBitsOut  = (U32)((symbolTT.deltaNbBits + (1<<15)) >> 16);
535
        statePtr->value = (nbBitsOut << 16) - symbolTT.deltaNbBits;
536
        statePtr->value = stateTable[(statePtr->value >> nbBitsOut) + symbolTT.deltaFindState];
537
    }
538
}
539

540
MEM_STATIC void FSE_encodeSymbol(BIT_CStream_t* bitC, FSE_CState_t* statePtr, unsigned symbol)
541
{
542
    FSE_symbolCompressionTransform const symbolTT = ((const FSE_symbolCompressionTransform*)(statePtr->symbolTT))[symbol];
543
    const U16* const stateTable = (const U16*)(statePtr->stateTable);
544
    U32 const nbBitsOut  = (U32)((statePtr->value + symbolTT.deltaNbBits) >> 16);
545
    BIT_addBits(bitC, statePtr->value, nbBitsOut);
546
    statePtr->value = stateTable[ (statePtr->value >> nbBitsOut) + symbolTT.deltaFindState];
547
}
548

549
MEM_STATIC void FSE_flushCState(BIT_CStream_t* bitC, const FSE_CState_t* statePtr)
550
{
551
    BIT_addBits(bitC, statePtr->value, statePtr->stateLog);
552
    BIT_flushBits(bitC);
553
}
554

555

556
/* FSE_getMaxNbBits() :
557
 * Approximate maximum cost of a symbol, in bits.
558
 * Fractional get rounded up (i.e : a symbol with a normalized frequency of 3 gives the same result as a frequency of 2)
559
 * note 1 : assume symbolValue is valid (<= maxSymbolValue)
560
 * note 2 : if freq[symbolValue]==0, @return a fake cost of tableLog+1 bits */
561
MEM_STATIC U32 FSE_getMaxNbBits(const void* symbolTTPtr, U32 symbolValue)
562
{
563
    const FSE_symbolCompressionTransform* symbolTT = (const FSE_symbolCompressionTransform*) symbolTTPtr;
564
    return (symbolTT[symbolValue].deltaNbBits + ((1<<16)-1)) >> 16;
565
}
566

567
/* FSE_bitCost() :
568
 * Approximate symbol cost, as fractional value, using fixed-point format (accuracyLog fractional bits)
569
 * note 1 : assume symbolValue is valid (<= maxSymbolValue)
570
 * note 2 : if freq[symbolValue]==0, @return a fake cost of tableLog+1 bits */
571
MEM_STATIC U32 FSE_bitCost(const void* symbolTTPtr, U32 tableLog, U32 symbolValue, U32 accuracyLog)
572
{
573
    const FSE_symbolCompressionTransform* symbolTT = (const FSE_symbolCompressionTransform*) symbolTTPtr;
574
    U32 const minNbBits = symbolTT[symbolValue].deltaNbBits >> 16;
575
    U32 const threshold = (minNbBits+1) << 16;
576
    assert(tableLog < 16);
577
    assert(accuracyLog < 31-tableLog);  /* ensure enough room for renormalization double shift */
578
    {   U32 const tableSize = 1 << tableLog;
579
        U32 const deltaFromThreshold = threshold - (symbolTT[symbolValue].deltaNbBits + tableSize);
580
        U32 const normalizedDeltaFromThreshold = (deltaFromThreshold << accuracyLog) >> tableLog;   /* linear interpolation (very approximate) */
581
        U32 const bitMultiplier = 1 << accuracyLog;
582
        assert(symbolTT[symbolValue].deltaNbBits + tableSize <= threshold);
583
        assert(normalizedDeltaFromThreshold <= bitMultiplier);
584
        return (minNbBits+1)*bitMultiplier - normalizedDeltaFromThreshold;
585
    }
586
}
587

588

589
/* ======    Decompression    ====== */
590

591
typedef struct {
592
    U16 tableLog;
593
    U16 fastMode;
594
} FSE_DTableHeader;   /* sizeof U32 */
595

596
typedef struct
597
{
598
    unsigned short newState;
599
    unsigned char  symbol;
600
    unsigned char  nbBits;
601
} FSE_decode_t;   /* size == U32 */
602

603
MEM_STATIC void FSE_initDState(FSE_DState_t* DStatePtr, BIT_DStream_t* bitD, const FSE_DTable* dt)
604
{
605
    const void* ptr = dt;
606
    const FSE_DTableHeader* const DTableH = (const FSE_DTableHeader*)ptr;
607
    DStatePtr->state = BIT_readBits(bitD, DTableH->tableLog);
608
    BIT_reloadDStream(bitD);
609
    DStatePtr->table = dt + 1;
610
}
611

612
MEM_STATIC BYTE FSE_peekSymbol(const FSE_DState_t* DStatePtr)
613
{
614
    FSE_decode_t const DInfo = ((const FSE_decode_t*)(DStatePtr->table))[DStatePtr->state];
615
    return DInfo.symbol;
616
}
617

618
MEM_STATIC void FSE_updateState(FSE_DState_t* DStatePtr, BIT_DStream_t* bitD)
619
{
620
    FSE_decode_t const DInfo = ((const FSE_decode_t*)(DStatePtr->table))[DStatePtr->state];
621
    U32 const nbBits = DInfo.nbBits;
622
    size_t const lowBits = BIT_readBits(bitD, nbBits);
623
    DStatePtr->state = DInfo.newState + lowBits;
624
}
625

626
MEM_STATIC BYTE FSE_decodeSymbol(FSE_DState_t* DStatePtr, BIT_DStream_t* bitD)
627
{
628
    FSE_decode_t const DInfo = ((const FSE_decode_t*)(DStatePtr->table))[DStatePtr->state];
629
    U32 const nbBits = DInfo.nbBits;
630
    BYTE const symbol = DInfo.symbol;
631
    size_t const lowBits = BIT_readBits(bitD, nbBits);
632

633
    DStatePtr->state = DInfo.newState + lowBits;
634
    return symbol;
635
}
636

637
/*! FSE_decodeSymbolFast() :
638
    unsafe, only works if no symbol has a probability > 50% */
639
MEM_STATIC BYTE FSE_decodeSymbolFast(FSE_DState_t* DStatePtr, BIT_DStream_t* bitD)
640
{
641
    FSE_decode_t const DInfo = ((const FSE_decode_t*)(DStatePtr->table))[DStatePtr->state];
642
    U32 const nbBits = DInfo.nbBits;
643
    BYTE const symbol = DInfo.symbol;
644
    size_t const lowBits = BIT_readBitsFast(bitD, nbBits);
645

646
    DStatePtr->state = DInfo.newState + lowBits;
647
    return symbol;
648
}
649

650
MEM_STATIC unsigned FSE_endOfDState(const FSE_DState_t* DStatePtr)
651
{
652
    return DStatePtr->state == 0;
653
}
654

655

656

657
#ifndef FSE_COMMONDEFS_ONLY
658

659
/* **************************************************************
660
*  Tuning parameters
661
****************************************************************/
662
/*!MEMORY_USAGE :
663
*  Memory usage formula : N->2^N Bytes (examples : 10 -> 1KB; 12 -> 4KB ; 16 -> 64KB; 20 -> 1MB; etc.)
664
*  Increasing memory usage improves compression ratio
665
*  Reduced memory usage can improve speed, due to cache effect
666
*  Recommended max value is 14, for 16KB, which nicely fits into Intel x86 L1 cache */
667
#ifndef FSE_MAX_MEMORY_USAGE
668
#  define FSE_MAX_MEMORY_USAGE 14
669
#endif
670
#ifndef FSE_DEFAULT_MEMORY_USAGE
671
#  define FSE_DEFAULT_MEMORY_USAGE 13
672
#endif
673
#if (FSE_DEFAULT_MEMORY_USAGE > FSE_MAX_MEMORY_USAGE)
674
#  error "FSE_DEFAULT_MEMORY_USAGE must be <= FSE_MAX_MEMORY_USAGE"
675
#endif
676

677
/*!FSE_MAX_SYMBOL_VALUE :
678
*  Maximum symbol value authorized.
679
*  Required for proper stack allocation */
680
#ifndef FSE_MAX_SYMBOL_VALUE
681
#  define FSE_MAX_SYMBOL_VALUE 255
682
#endif
683

684
/* **************************************************************
685
*  template functions type & suffix
686
****************************************************************/
687
#define FSE_FUNCTION_TYPE BYTE
688
#define FSE_FUNCTION_EXTENSION
689
#define FSE_DECODE_TYPE FSE_decode_t
690

691

692
#endif   /* !FSE_COMMONDEFS_ONLY */
693

694

695
/* ***************************************************************
696
*  Constants
697
*****************************************************************/
698
#define FSE_MAX_TABLELOG  (FSE_MAX_MEMORY_USAGE-2)
699
#define FSE_MAX_TABLESIZE (1U<<FSE_MAX_TABLELOG)
700
#define FSE_MAXTABLESIZE_MASK (FSE_MAX_TABLESIZE-1)
701
#define FSE_DEFAULT_TABLELOG (FSE_DEFAULT_MEMORY_USAGE-2)
702
#define FSE_MIN_TABLELOG 5
703

704
#define FSE_TABLELOG_ABSOLUTE_MAX 15
705
#if FSE_MAX_TABLELOG > FSE_TABLELOG_ABSOLUTE_MAX
706
#  error "FSE_MAX_TABLELOG > FSE_TABLELOG_ABSOLUTE_MAX is not supported"
707
#endif
708

709
#define FSE_TABLESTEP(tableSize) (((tableSize)>>1) + ((tableSize)>>3) + 3)
710

711

712
#endif /* FSE_STATIC_LINKING_ONLY */
713

714

715
#if defined (__cplusplus)
716
}
717
#endif
718

719