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576 lines
26 KiB
C
576 lines
26 KiB
C
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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) 2013-2016, Yann Collet.
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*
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* BSD 2-Clause License (http://www.opensource.org/licenses/bsd-license.php)
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions are
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* met:
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*
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* * Redistributions of source code must retain the above copyright
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* notice, this list of conditions and the following disclaimer.
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* * Redistributions in binary form must reproduce the above
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* copyright notice, this list of conditions and the following disclaimer
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* in the documentation and/or other materials provided with the
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* distribution.
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*
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* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*
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* This program is free software; you can redistribute it and/or modify it under
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* the terms of the GNU General Public License version 2 as published by the
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* Free Software Foundation. This program is dual-licensed; you may select
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* either version 2 of the GNU General Public License ("GPL") or BSD license
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* ("BSD").
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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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#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 <linux/types.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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#define FSE_PUBLIC_API
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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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* 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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/*-*****************************************
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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[]
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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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@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, const unsigned *count, size_t srcSize, unsigned maxSymbolValue);
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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, const short *normalizedCounter, 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_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, unsigned *maxSymbolValuePtr, unsigned *tableLogPtr, const void *rBuffer, size_t rBuffSize);
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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_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_wksp(FSE_DTable *dt, const short *normalizedCounter, unsigned maxSymbolValue, unsigned tableLog, void *workspace, size_t workspaceSize);
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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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/* *** 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))
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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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/* *****************************************
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* FSE advanced API
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*******************************************/
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/* FSE_count_wksp() :
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* Same as FSE_count(), but using an externally provided scratch buffer.
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* `workSpace` size must be table of >= `1024` unsigned
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*/
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size_t FSE_count_wksp(unsigned *count, unsigned *maxSymbolValuePtr, const void *source, size_t sourceSize, unsigned *workSpace);
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/* FSE_countFast_wksp() :
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* Same as FSE_countFast(), but using an externally provided scratch buffer.
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* `workSpace` must be a table of minimum `1024` unsigned
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*/
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size_t FSE_countFast_wksp(unsigned *count, unsigned *maxSymbolValuePtr, const void *src, size_t srcSize, unsigned *workSpace);
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/*! FSE_count_simple
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* Same as FSE_countFast(), but does not use any additional memory (not even on stack).
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* This function is unsafe, and will segfault if any value within `src` is `> *maxSymbolValuePtr` (presuming it's also the size of `count`).
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*/
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size_t FSE_count_simple(unsigned *count, unsigned *maxSymbolValuePtr, const void *src, size_t srcSize);
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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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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 >= `(1<<tableLog)`.
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*/
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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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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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size_t FSE_decompress_wksp(void *dst, size_t dstCapacity, const void *cSrc, size_t cSrcSize, unsigned maxLog, void *workspace, size_t workspaceSize);
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/**< same as FSE_decompress(), using an externally allocated `workSpace` produced with `FSE_DTABLE_SIZE_U32(maxLog)` */
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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);
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Your last FSE encoding operation shall be to flush your last state value(s).
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FSE_flushState(&bitStream, &state);
|
||
|
|
||
|
Finally, you must close the bitStream.
|
||
|
The function returns the size of CStream in bytes.
|
||
|
If data couldn't fit into dstBuffer, it will return a 0 ( == not compressible)
|
||
|
If there is an error, it returns an errorCode (which can be tested using FSE_isError()).
|
||
|
size_t size = BIT_closeCStream(&bitStream);
|
||
|
*/
|
||
|
|
||
|
/* *****************************************
|
||
|
* FSE symbol decompression API
|
||
|
*******************************************/
|
||
|
typedef struct {
|
||
|
size_t state;
|
||
|
const void *table; /* precise table may vary, depending on U16 */
|
||
|
} FSE_DState_t;
|
||
|
|
||
|
static void FSE_initDState(FSE_DState_t *DStatePtr, BIT_DStream_t *bitD, const FSE_DTable *dt);
|
||
|
|
||
|
static unsigned char FSE_decodeSymbol(FSE_DState_t *DStatePtr, BIT_DStream_t *bitD);
|
||
|
|
||
|
static unsigned FSE_endOfDState(const FSE_DState_t *DStatePtr);
|
||
|
|
||
|
/**<
|
||
|
Let's now decompose FSE_decompress_usingDTable() into its unitary components.
|
||
|
You will decode FSE-encoded symbols from the bitStream,
|
||
|
and also any other bitFields you put in, **in reverse order**.
|
||
|
|
||
|
You will need a few variables to track your bitStream. They are :
|
||
|
|
||
|
BIT_DStream_t DStream; // Stream context
|
||
|
FSE_DState_t DState; // State context. Multiple ones are possible
|
||
|
FSE_DTable* DTablePtr; // Decoding table, provided by FSE_buildDTable()
|
||
|
|
||
|
The first thing to do is to init the bitStream.
|
||
|
errorCode = BIT_initDStream(&DStream, srcBuffer, srcSize);
|
||
|
|
||
|
You should then retrieve your initial state(s)
|
||
|
(in reverse flushing order if you have several ones) :
|
||
|
errorCode = FSE_initDState(&DState, &DStream, DTablePtr);
|
||
|
|
||
|
You can then decode your data, symbol after symbol.
|
||
|
For information the maximum number of bits read by FSE_decodeSymbol() is 'tableLog'.
|
||
|
Keep in mind that symbols are decoded in reverse order, like a LIFO stack (last in, first out).
|
||
|
unsigned char symbol = FSE_decodeSymbol(&DState, &DStream);
|
||
|
|
||
|
You can retrieve any bitfield you eventually stored into the bitStream (in reverse order)
|
||
|
Note : maximum allowed nbBits is 25, for 32-bits compatibility
|
||
|
size_t bitField = BIT_readBits(&DStream, nbBits);
|
||
|
|
||
|
All above operations only read from local register (which size depends on size_t).
|
||
|
Refueling the register from memory is manually performed by the reload method.
|
||
|
endSignal = FSE_reloadDStream(&DStream);
|
||
|
|
||
|
BIT_reloadDStream() result tells if there is still some more data to read from DStream.
|
||
|
BIT_DStream_unfinished : there is still some data left into the DStream.
|
||
|
BIT_DStream_endOfBuffer : Dstream reached end of buffer. Its container may no longer be completely filled.
|
||
|
BIT_DStream_completed : Dstream reached its exact end, corresponding in general to decompression completed.
|
||
|
BIT_DStream_tooFar : Dstream went too far. Decompression result is corrupted.
|
||
|
|
||
|
When reaching end of buffer (BIT_DStream_endOfBuffer), progress slowly, notably if you decode multiple symbols per loop,
|
||
|
to properly detect the exact end of stream.
|
||
|
After each decoded symbol, check if DStream is fully consumed using this simple test :
|
||
|
BIT_reloadDStream(&DStream) >= BIT_DStream_completed
|
||
|
|
||
|
When it's done, verify decompression is fully completed, by checking both DStream and the relevant states.
|
||
|
Checking if DStream has reached its end is performed by :
|
||
|
BIT_endOfDStream(&DStream);
|
||
|
Check also the states. There might be some symbols left there, if some high probability ones (>50%) are possible.
|
||
|
FSE_endOfDState(&DState);
|
||
|
*/
|
||
|
|
||
|
/* *****************************************
|
||
|
* FSE unsafe API
|
||
|
*******************************************/
|
||
|
static unsigned char FSE_decodeSymbolFast(FSE_DState_t *DStatePtr, BIT_DStream_t *bitD);
|
||
|
/* faster, but works only if nbBits is always >= 1 (otherwise, result will be corrupted) */
|
||
|
|
||
|
/* *****************************************
|
||
|
* Implementation of inlined functions
|
||
|
*******************************************/
|
||
|
typedef struct {
|
||
|
int deltaFindState;
|
||
|
U32 deltaNbBits;
|
||
|
} FSE_symbolCompressionTransform; /* total 8 bytes */
|
||
|
|
||
|
ZSTD_STATIC void FSE_initCState(FSE_CState_t *statePtr, const FSE_CTable *ct)
|
||
|
{
|
||
|
const void *ptr = ct;
|
||
|
const U16 *u16ptr = (const U16 *)ptr;
|
||
|
const U32 tableLog = ZSTD_read16(ptr);
|
||
|
statePtr->value = (ptrdiff_t)1 << tableLog;
|
||
|
statePtr->stateTable = u16ptr + 2;
|
||
|
statePtr->symbolTT = ((const U32 *)ct + 1 + (tableLog ? (1 << (tableLog - 1)) : 1));
|
||
|
statePtr->stateLog = tableLog;
|
||
|
}
|
||
|
|
||
|
/*! FSE_initCState2() :
|
||
|
* Same as FSE_initCState(), but the first symbol to include (which will be the last to be read)
|
||
|
* uses the smallest state value possible, saving the cost of this symbol */
|
||
|
ZSTD_STATIC void FSE_initCState2(FSE_CState_t *statePtr, const FSE_CTable *ct, U32 symbol)
|
||
|
{
|
||
|
FSE_initCState(statePtr, ct);
|
||
|
{
|
||
|
const FSE_symbolCompressionTransform symbolTT = ((const FSE_symbolCompressionTransform *)(statePtr->symbolTT))[symbol];
|
||
|
const U16 *stateTable = (const U16 *)(statePtr->stateTable);
|
||
|
U32 nbBitsOut = (U32)((symbolTT.deltaNbBits + (1 << 15)) >> 16);
|
||
|
statePtr->value = (nbBitsOut << 16) - symbolTT.deltaNbBits;
|
||
|
statePtr->value = stateTable[(statePtr->value >> nbBitsOut) + symbolTT.deltaFindState];
|
||
|
}
|
||
|
}
|
||
|
|
||
|
ZSTD_STATIC void FSE_encodeSymbol(BIT_CStream_t *bitC, FSE_CState_t *statePtr, U32 symbol)
|
||
|
{
|
||
|
const FSE_symbolCompressionTransform symbolTT = ((const FSE_symbolCompressionTransform *)(statePtr->symbolTT))[symbol];
|
||
|
const U16 *const stateTable = (const U16 *)(statePtr->stateTable);
|
||
|
U32 nbBitsOut = (U32)((statePtr->value + symbolTT.deltaNbBits) >> 16);
|
||
|
BIT_addBits(bitC, statePtr->value, nbBitsOut);
|
||
|
statePtr->value = stateTable[(statePtr->value >> nbBitsOut) + symbolTT.deltaFindState];
|
||
|
}
|
||
|
|
||
|
ZSTD_STATIC void FSE_flushCState(BIT_CStream_t *bitC, const FSE_CState_t *statePtr)
|
||
|
{
|
||
|
BIT_addBits(bitC, statePtr->value, statePtr->stateLog);
|
||
|
BIT_flushBits(bitC);
|
||
|
}
|
||
|
|
||
|
/* ====== Decompression ====== */
|
||
|
|
||
|
typedef struct {
|
||
|
U16 tableLog;
|
||
|
U16 fastMode;
|
||
|
} FSE_DTableHeader; /* sizeof U32 */
|
||
|
|
||
|
typedef struct {
|
||
|
unsigned short newState;
|
||
|
unsigned char symbol;
|
||
|
unsigned char nbBits;
|
||
|
} FSE_decode_t; /* size == U32 */
|
||
|
|
||
|
ZSTD_STATIC void FSE_initDState(FSE_DState_t *DStatePtr, BIT_DStream_t *bitD, const FSE_DTable *dt)
|
||
|
{
|
||
|
const void *ptr = dt;
|
||
|
const FSE_DTableHeader *const DTableH = (const FSE_DTableHeader *)ptr;
|
||
|
DStatePtr->state = BIT_readBits(bitD, DTableH->tableLog);
|
||
|
BIT_reloadDStream(bitD);
|
||
|
DStatePtr->table = dt + 1;
|
||
|
}
|
||
|
|
||
|
ZSTD_STATIC BYTE FSE_peekSymbol(const FSE_DState_t *DStatePtr)
|
||
|
{
|
||
|
FSE_decode_t const DInfo = ((const FSE_decode_t *)(DStatePtr->table))[DStatePtr->state];
|
||
|
return DInfo.symbol;
|
||
|
}
|
||
|
|
||
|
ZSTD_STATIC void FSE_updateState(FSE_DState_t *DStatePtr, BIT_DStream_t *bitD)
|
||
|
{
|
||
|
FSE_decode_t const DInfo = ((const FSE_decode_t *)(DStatePtr->table))[DStatePtr->state];
|
||
|
U32 const nbBits = DInfo.nbBits;
|
||
|
size_t const lowBits = BIT_readBits(bitD, nbBits);
|
||
|
DStatePtr->state = DInfo.newState + lowBits;
|
||
|
}
|
||
|
|
||
|
ZSTD_STATIC BYTE FSE_decodeSymbol(FSE_DState_t *DStatePtr, BIT_DStream_t *bitD)
|
||
|
{
|
||
|
FSE_decode_t const DInfo = ((const FSE_decode_t *)(DStatePtr->table))[DStatePtr->state];
|
||
|
U32 const nbBits = DInfo.nbBits;
|
||
|
BYTE const symbol = DInfo.symbol;
|
||
|
size_t const lowBits = BIT_readBits(bitD, nbBits);
|
||
|
|
||
|
DStatePtr->state = DInfo.newState + lowBits;
|
||
|
return symbol;
|
||
|
}
|
||
|
|
||
|
/*! FSE_decodeSymbolFast() :
|
||
|
unsafe, only works if no symbol has a probability > 50% */
|
||
|
ZSTD_STATIC BYTE FSE_decodeSymbolFast(FSE_DState_t *DStatePtr, BIT_DStream_t *bitD)
|
||
|
{
|
||
|
FSE_decode_t const DInfo = ((const FSE_decode_t *)(DStatePtr->table))[DStatePtr->state];
|
||
|
U32 const nbBits = DInfo.nbBits;
|
||
|
BYTE const symbol = DInfo.symbol;
|
||
|
size_t const lowBits = BIT_readBitsFast(bitD, nbBits);
|
||
|
|
||
|
DStatePtr->state = DInfo.newState + lowBits;
|
||
|
return symbol;
|
||
|
}
|
||
|
|
||
|
ZSTD_STATIC unsigned FSE_endOfDState(const FSE_DState_t *DStatePtr) { return DStatePtr->state == 0; }
|
||
|
|
||
|
/* **************************************************************
|
||
|
* Tuning parameters
|
||
|
****************************************************************/
|
||
|
/*!MEMORY_USAGE :
|
||
|
* Memory usage formula : N->2^N Bytes (examples : 10 -> 1KB; 12 -> 4KB ; 16 -> 64KB; 20 -> 1MB; etc.)
|
||
|
* Increasing memory usage improves compression ratio
|
||
|
* Reduced memory usage can improve speed, due to cache effect
|
||
|
* Recommended max value is 14, for 16KB, which nicely fits into Intel x86 L1 cache */
|
||
|
#ifndef FSE_MAX_MEMORY_USAGE
|
||
|
#define FSE_MAX_MEMORY_USAGE 14
|
||
|
#endif
|
||
|
#ifndef FSE_DEFAULT_MEMORY_USAGE
|
||
|
#define FSE_DEFAULT_MEMORY_USAGE 13
|
||
|
#endif
|
||
|
|
||
|
/*!FSE_MAX_SYMBOL_VALUE :
|
||
|
* Maximum symbol value authorized.
|
||
|
* Required for proper stack allocation */
|
||
|
#ifndef FSE_MAX_SYMBOL_VALUE
|
||
|
#define FSE_MAX_SYMBOL_VALUE 255
|
||
|
#endif
|
||
|
|
||
|
/* **************************************************************
|
||
|
* template functions type & suffix
|
||
|
****************************************************************/
|
||
|
#define FSE_FUNCTION_TYPE BYTE
|
||
|
#define FSE_FUNCTION_EXTENSION
|
||
|
#define FSE_DECODE_TYPE FSE_decode_t
|
||
|
|
||
|
/* ***************************************************************
|
||
|
* Constants
|
||
|
*****************************************************************/
|
||
|
#define FSE_MAX_TABLELOG (FSE_MAX_MEMORY_USAGE - 2)
|
||
|
#define FSE_MAX_TABLESIZE (1U << FSE_MAX_TABLELOG)
|
||
|
#define FSE_MAXTABLESIZE_MASK (FSE_MAX_TABLESIZE - 1)
|
||
|
#define FSE_DEFAULT_TABLELOG (FSE_DEFAULT_MEMORY_USAGE - 2)
|
||
|
#define FSE_MIN_TABLELOG 5
|
||
|
|
||
|
#define FSE_TABLELOG_ABSOLUTE_MAX 15
|
||
|
#if FSE_MAX_TABLELOG > FSE_TABLELOG_ABSOLUTE_MAX
|
||
|
#error "FSE_MAX_TABLELOG > FSE_TABLELOG_ABSOLUTE_MAX is not supported"
|
||
|
#endif
|
||
|
|
||
|
#define FSE_TABLESTEP(tableSize) ((tableSize >> 1) + (tableSize >> 3) + 3)
|
||
|
|
||
|
#endif /* FSE_H */
|