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#include <contrib/libs/zstd06/renames.h>
/* ****************************************************************** 
   FSE : Finite State Entropy coder 
   header file for static linking (only) 
   Copyright (C) 2013-2015, Yann Collet 
 
   BSD 2-Clause License (http://www.opensource.org/licenses/bsd-license.php) 
 
   Redistribution and use in source and binary forms, with or without 
   modification, are permitted provided that the following conditions are 
   met: 
 
       * Redistributions of source code must retain the above copyright 
   notice, this list of conditions and the following disclaimer. 
       * Redistributions in binary form must reproduce the above 
   copyright notice, this list of conditions and the following disclaimer 
   in the documentation and/or other materials provided with the 
   distribution. 
 
   THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 
   "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 
   LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 
   A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 
   OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 
   SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 
   LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 
   DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 
   THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 
   (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 
   OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 
 
   You can contact the author at : 
   - Source repository : https://github.com/Cyan4973/FiniteStateEntropy 
   - Public forum : https://groups.google.com/forum/#!forum/lz4c 
****************************************************************** */ 
#ifndef FSE_STATIC_H 
#define FSE_STATIC_H 
 
#if defined (__cplusplus) 
extern "C" { 
#endif 
 
 
/* ***************************************** 
*  Dependencies 
*******************************************/ 
#include "fse.h" 
#include "bitstream.h" 
 
 
/* ***************************************** 
*  Static allocation 
*******************************************/ 
/* FSE buffer bounds */ 
#define FSE_NCOUNTBOUND 512 
#define FSE_BLOCKBOUND(size) (size + (size>>7)) 
#define FSE_COMPRESSBOUND(size) (FSE_NCOUNTBOUND + FSE_BLOCKBOUND(size))   /* Macro version, useful for static allocation */ 
 
/* It is possible to statically allocate FSE CTable/DTable as a table of unsigned using below macros */ 
#define FSE_CTABLE_SIZE_U32(maxTableLog, maxSymbolValue)   (1 + (1<<(maxTableLog-1)) + ((maxSymbolValue+1)*2)) 
#define FSE_DTABLE_SIZE_U32(maxTableLog)                   (1 + (1<<maxTableLog)) 
 
 
/* ***************************************** 
*  FSE advanced API 
*******************************************/ 
size_t FSE_countFast(unsigned* count, unsigned* maxSymbolValuePtr, const void* src, size_t srcSize); 
/* same as FSE_count(), but blindly trusts that all byte values within src are <= *maxSymbolValuePtr  */ 
 
size_t FSE_buildCTable_raw (FSE_CTable* ct, unsigned nbBits); 
/* build a fake FSE_CTable, designed to not compress an input, where each symbol uses nbBits */ 
 
size_t FSE_buildCTable_rle (FSE_CTable* ct, unsigned char symbolValue); 
/* build a fake FSE_CTable, designed to compress always the same symbolValue */ 
 
size_t FSE_buildDTable_raw (FSE_DTable* dt, unsigned nbBits); 
/* build a fake FSE_DTable, designed to read an uncompressed bitstream where each symbol uses nbBits */ 
 
size_t FSE_buildDTable_rle (FSE_DTable* dt, unsigned char symbolValue); 
/* build a fake FSE_DTable, designed to always generate the same symbolValue */ 
 
 
/* ***************************************** 
*  FSE symbol compression API 
*******************************************/ 
/*! 
   This API consists of small unitary functions, which highly benefit from being inlined. 
   You will want to enable link-time-optimization to ensure these functions are properly inlined in your binary. 
   Visual seems to do it automatically. 
   For gcc or clang, you'll need to add -flto flag at compilation and linking stages. 
   If none of these solutions is applicable, include "fse.c" directly. 
*/ 
typedef struct 
{ 
    ptrdiff_t   value; 
    const void* stateTable; 
    const void* symbolTT; 
    unsigned    stateLog; 
} FSE_CState_t; 
 
static void FSE_initCState(FSE_CState_t* CStatePtr, const FSE_CTable* ct); 
 
static void FSE_encodeSymbol(BIT_CStream_t* bitC, FSE_CState_t* CStatePtr, unsigned symbol); 
 
static void FSE_flushCState(BIT_CStream_t* bitC, const FSE_CState_t* CStatePtr); 
 
/*! 
These functions are inner components of FSE_compress_usingCTable(). 
They allow the creation of custom streams, mixing multiple tables and bit sources. 
 
A key property to keep in mind is that encoding and decoding are done **in reverse direction**. 
So the first symbol you will encode is the last you will decode, like a LIFO stack. 
 
You will need a few variables to track your CStream. They are : 
 
FSE_CTable    ct;         // Provided by FSE_buildCTable() 
BIT_CStream_t bitStream;  // bitStream tracking structure 
FSE_CState_t  state;      // State tracking structure (can have several) 
 
 
The first thing to do is to init bitStream and state. 
    size_t errorCode = BIT_initCStream(&bitStream, dstBuffer, maxDstSize); 
    FSE_initCState(&state, ct); 
 
Note that BIT_initCStream() can produce an error code, so its result should be tested, using FSE_isError(); 
You can then encode your input data, byte after byte. 
FSE_encodeSymbol() outputs a maximum of 'tableLog' bits at a time. 
Remember decoding will be done in reverse direction. 
    FSE_encodeByte(&bitStream, &state, symbol); 
 
At any time, you can also add any bit sequence. 
Note : maximum allowed nbBits is 25, for compatibility with 32-bits decoders 
    BIT_addBits(&bitStream, bitField, nbBits); 
 
The above methods don't commit data to memory, they just store it into local register, for speed. 
Local register size is 64-bits on 64-bits systems, 32-bits on 32-bits systems (size_t). 
Writing data to memory is a manual operation, performed by the flushBits function. 
    BIT_flushBits(&bitStream); 
 
Your last FSE encoding operation shall be to flush your last state value(s). 
    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 */ 
 
MEM_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 = MEM_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; 
} 
 
MEM_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]; 
 
    } 
} 
 
MEM_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]; 
} 
 
MEM_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 */ 
 
MEM_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; 
} 
 
MEM_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; 
} 
 
MEM_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; 
} 
 
MEM_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% */ 
MEM_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; 
} 
 
MEM_STATIC unsigned FSE_endOfDState(const FSE_DState_t* DStatePtr) 
{ 
    return DStatePtr->state == 0; 
} 
 
 

#ifndef FSE_COMMONDEFS_ONLY

/* **************************************************************
*  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 */
#define FSE_MAX_MEMORY_USAGE 14
#define FSE_DEFAULT_MEMORY_USAGE 13

/*!FSE_MAX_SYMBOL_VALUE :
*  Maximum symbol value authorized.
*  Required for proper stack allocation */
#define FSE_MAX_SYMBOL_VALUE 255


/* **************************************************************
*  template functions type & suffix
****************************************************************/
#define FSE_FUNCTION_TYPE BYTE
#define FSE_FUNCTION_EXTENSION
#define FSE_DECODE_TYPE FSE_decode_t


#endif   /* !FSE_COMMONDEFS_ONLY */


/* ***************************************************************
*  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)


#if defined (__cplusplus) 
} 
#endif 
 
#endif  /* FSE_STATIC_H */