lz4/lib/xxhash.c

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/*
xxHash - Fast Hash algorithm
Copyright (C) 2012-2015, Yann Collet
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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 :
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- xxHash source repository : https://github.com/Cyan4973/xxHash
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*/
/**************************************
* Tuning parameters
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**************************************/
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/* XXH_FORCE_MEMORY_ACCESS
* By default, access to unaligned memory is controlled by `memcpy()`, which is safe and portable.
* Unfortunately, on some target/compiler combinations, the generated assembly is sub-optimal.
* The below switch allow to select different access method for improved performance.
* Method 0 (default) : use `memcpy()`. Safe and portable.
* Method 1 : `__packed` statement. It depends on compiler extension (ie, not portable).
* This method is safe if your compiler supports it, and *generally* as fast or faster than `memcpy`.
* Method 2 : direct access. This method is portable but violate C standard.
* It can generate buggy code on targets which generate assembly depending on alignment.
* But in some circumstances, it's the only known way to get the most performance (ie GCC + ARMv6)
* See http://stackoverflow.com/a/32095106/646947 for details.
* Prefer these methods in priority order (0 > 1 > 2)
*/
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#ifndef XXH_FORCE_MEMORY_ACCESS /* can be defined externally, on command line for example */
# if defined(__GNUC__) && ( defined(__ARM_ARCH_6__) || defined(__ARM_ARCH_6J__) || defined(__ARM_ARCH_6K__) || defined(__ARM_ARCH_6Z__) || defined(__ARM_ARCH_6ZK__) || defined(__ARM_ARCH_6T2__) )
# define XXH_FORCE_MEMORY_ACCESS 2
# elif defined(__INTEL_COMPILER) || \
(defined(__GNUC__) && ( defined(__ARM_ARCH_7__) || defined(__ARM_ARCH_7A__) || defined(__ARM_ARCH_7R__) || defined(__ARM_ARCH_7M__) || defined(__ARM_ARCH_7S__) ))
# define XXH_FORCE_MEMORY_ACCESS 1
# endif
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#endif
/* XXH_ACCEPT_NULL_INPUT_POINTER :
* If the input pointer is a null pointer, xxHash default behavior is to trigger a memory access error, since it is a bad pointer.
* When this option is enabled, xxHash output for null input pointers will be the same as a null-length input.
* By default, this option is disabled. To enable it, uncomment below define :
*/
/* #define XXH_ACCEPT_NULL_INPUT_POINTER 1 */
/* XXH_FORCE_NATIVE_FORMAT :
* By default, xxHash library provides endian-independant Hash values, based on little-endian convention.
* Results are therefore identical for little-endian and big-endian CPU.
* This comes at a performance cost for big-endian CPU, since some swapping is required to emulate little-endian format.
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* Should endian-independance be of no importance for your application, you may set the #define below to 1,
* to improve speed for Big-endian CPU.
* This option has no impact on Little_Endian CPU.
*/
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#define XXH_FORCE_NATIVE_FORMAT 0
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/* XXH_USELESS_ALIGN_BRANCH :
* This is a minor performance trick, only useful with lots of very small keys.
* It means : don't make a test between aligned/unaligned, because performance will be the same.
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* It saves one initial branch per hash.
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*/
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#if defined(__i386) || defined(_M_IX86) || defined(__x86_64__) || defined(_M_X64)
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# define XXH_USELESS_ALIGN_BRANCH 1
#endif
/**************************************
* Compiler Specific Options
***************************************/
#ifdef _MSC_VER /* Visual Studio */
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# pragma warning(disable : 4127) /* disable: C4127: conditional expression is constant */
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# define FORCE_INLINE static __forceinline
#else
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# if defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L /* C99 */
# ifdef __GNUC__
# define FORCE_INLINE static inline __attribute__((always_inline))
# else
# define FORCE_INLINE static inline
# endif
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# else
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# define FORCE_INLINE static
# endif /* __STDC_VERSION__ */
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#endif
/**************************************
* Includes & Memory related functions
***************************************/
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#include "xxhash.h"
/* Modify the local functions below should you wish to use some other memory routines */
/* for malloc(), free() */
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#include <stdlib.h>
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static void* XXH_malloc(size_t s) { return malloc(s); }
static void XXH_free (void* p) { free(p); }
/* for memcpy() */
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#include <string.h>
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static void* XXH_memcpy(void* dest, const void* src, size_t size) { return memcpy(dest,src,size); }
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/**************************************
* Basic Types
***************************************/
#if defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L /* C99 */
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# include <stdint.h>
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typedef uint8_t BYTE;
typedef uint16_t U16;
typedef uint32_t U32;
typedef int32_t S32;
typedef uint64_t U64;
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#else
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typedef unsigned char BYTE;
typedef unsigned short U16;
typedef unsigned int U32;
typedef signed int S32;
typedef unsigned long long U64;
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#endif
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#if (defined(XXH_FORCE_MEMORY_ACCESS) && (XXH_FORCE_MEMORY_ACCESS==2))
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/* Force direct memory access. Only works on CPU which support unaligned memory access in hardware */
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static U32 XXH_read32(const void* memPtr) { return *(const U32*) memPtr; }
static U64 XXH_read64(const void* memPtr) { return *(const U64*) memPtr; }
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#elif (defined(XXH_FORCE_MEMORY_ACCESS) && (XXH_FORCE_MEMORY_ACCESS==1))
/* __pack instructions are safer, but compiler specific, hence potentially problematic for some compilers */
/* currently only defined for gcc and icc */
typedef union { U32 u32; U64 u64; } __attribute__((packed)) unalign;
static U32 XXH_read32(const void* ptr) { return ((const unalign*)ptr)->u32; }
static U64 XXH_read64(const void* ptr) { return ((const unalign*)ptr)->u64; }
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#else
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/* portable and safe solution. Generally efficient.
* see : http://stackoverflow.com/a/32095106/646947
*/
static U32 XXH_read32(const void* memPtr)
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{
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U32 val;
memcpy(&val, memPtr, sizeof(val));
return val;
}
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static U64 XXH_read64(const void* memPtr)
{
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U64 val;
memcpy(&val, memPtr, sizeof(val));
return val;
}
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#endif // XXH_FORCE_DIRECT_MEMORY_ACCESS
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/******************************************
* Compiler-specific Functions and Macros
******************************************/
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#define GCC_VERSION (__GNUC__ * 100 + __GNUC_MINOR__)
/* Note : although _rotl exists for minGW (GCC under windows), performance seems poor */
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#if defined(_MSC_VER)
# define XXH_rotl32(x,r) _rotl(x,r)
# define XXH_rotl64(x,r) _rotl64(x,r)
#else
# define XXH_rotl32(x,r) ((x << r) | (x >> (32 - r)))
# define XXH_rotl64(x,r) ((x << r) | (x >> (64 - r)))
#endif
#if defined(_MSC_VER) /* Visual Studio */
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# define XXH_swap32 _byteswap_ulong
# define XXH_swap64 _byteswap_uint64
#elif GCC_VERSION >= 403
# define XXH_swap32 __builtin_bswap32
# define XXH_swap64 __builtin_bswap64
#else
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static U32 XXH_swap32 (U32 x)
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{
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return ((x << 24) & 0xff000000 ) |
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((x << 8) & 0x00ff0000 ) |
((x >> 8) & 0x0000ff00 ) |
((x >> 24) & 0x000000ff );
}
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static U64 XXH_swap64 (U64 x)
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{
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return ((x << 56) & 0xff00000000000000ULL) |
((x << 40) & 0x00ff000000000000ULL) |
((x << 24) & 0x0000ff0000000000ULL) |
((x << 8) & 0x000000ff00000000ULL) |
((x >> 8) & 0x00000000ff000000ULL) |
((x >> 24) & 0x0000000000ff0000ULL) |
((x >> 40) & 0x000000000000ff00ULL) |
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((x >> 56) & 0x00000000000000ffULL);
}
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#endif
/***************************************
* Architecture Macros
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***************************************/
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typedef enum { XXH_bigEndian=0, XXH_littleEndian=1 } XXH_endianess;
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/* XXH_CPU_LITTLE_ENDIAN can be defined externally, for example one the compiler command line */
#ifndef XXH_CPU_LITTLE_ENDIAN
static const int one = 1;
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# define XXH_CPU_LITTLE_ENDIAN (*(const char*)(&one))
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#endif
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/*****************************
* Memory reads
*****************************/
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typedef enum { XXH_aligned, XXH_unaligned } XXH_alignment;
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FORCE_INLINE U32 XXH_readLE32_align(const void* ptr, XXH_endianess endian, XXH_alignment align)
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{
if (align==XXH_unaligned)
return endian==XXH_littleEndian ? XXH_read32(ptr) : XXH_swap32(XXH_read32(ptr));
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else
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return endian==XXH_littleEndian ? *(const U32*)ptr : XXH_swap32(*(const U32*)ptr);
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}
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FORCE_INLINE U32 XXH_readLE32(const void* ptr, XXH_endianess endian)
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{
return XXH_readLE32_align(ptr, endian, XXH_unaligned);
}
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FORCE_INLINE U64 XXH_readLE64_align(const void* ptr, XXH_endianess endian, XXH_alignment align)
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{
if (align==XXH_unaligned)
return endian==XXH_littleEndian ? XXH_read64(ptr) : XXH_swap64(XXH_read64(ptr));
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else
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return endian==XXH_littleEndian ? *(const U64*)ptr : XXH_swap64(*(const U64*)ptr);
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}
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FORCE_INLINE U64 XXH_readLE64(const void* ptr, XXH_endianess endian)
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{
return XXH_readLE64_align(ptr, endian, XXH_unaligned);
}
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/***************************************
* Macros
***************************************/
#define XXH_STATIC_ASSERT(c) { enum { XXH_static_assert = 1/(!!(c)) }; } /* use only *after* variable declarations */
/***************************************
* Constants
***************************************/
#define PRIME32_1 2654435761U
#define PRIME32_2 2246822519U
#define PRIME32_3 3266489917U
#define PRIME32_4 668265263U
#define PRIME32_5 374761393U
#define PRIME64_1 11400714785074694791ULL
#define PRIME64_2 14029467366897019727ULL
#define PRIME64_3 1609587929392839161ULL
#define PRIME64_4 9650029242287828579ULL
#define PRIME64_5 2870177450012600261ULL
/*****************************
* Simple Hash Functions
*****************************/
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FORCE_INLINE U32 XXH32_endian_align(const void* input, size_t len, U32 seed, XXH_endianess endian, XXH_alignment align)
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{
const BYTE* p = (const BYTE*)input;
const BYTE* bEnd = p + len;
U32 h32;
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#define XXH_get32bits(p) XXH_readLE32_align(p, endian, align)
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#ifdef XXH_ACCEPT_NULL_INPUT_POINTER
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if (p==NULL)
{
len=0;
bEnd=p=(const BYTE*)(size_t)16;
}
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#endif
if (len>=16)
{
const BYTE* const limit = bEnd - 16;
U32 v1 = seed + PRIME32_1 + PRIME32_2;
U32 v2 = seed + PRIME32_2;
U32 v3 = seed + 0;
U32 v4 = seed - PRIME32_1;
do
{
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v1 += XXH_get32bits(p) * PRIME32_2;
v1 = XXH_rotl32(v1, 13);
v1 *= PRIME32_1;
p+=4;
v2 += XXH_get32bits(p) * PRIME32_2;
v2 = XXH_rotl32(v2, 13);
v2 *= PRIME32_1;
p+=4;
v3 += XXH_get32bits(p) * PRIME32_2;
v3 = XXH_rotl32(v3, 13);
v3 *= PRIME32_1;
p+=4;
v4 += XXH_get32bits(p) * PRIME32_2;
v4 = XXH_rotl32(v4, 13);
v4 *= PRIME32_1;
p+=4;
}
while (p<=limit);
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h32 = XXH_rotl32(v1, 1) + XXH_rotl32(v2, 7) + XXH_rotl32(v3, 12) + XXH_rotl32(v4, 18);
}
else
{
h32 = seed + PRIME32_5;
}
h32 += (U32) len;
while (p+4<=bEnd)
{
h32 += XXH_get32bits(p) * PRIME32_3;
h32 = XXH_rotl32(h32, 17) * PRIME32_4 ;
p+=4;
}
while (p<bEnd)
{
h32 += (*p) * PRIME32_5;
h32 = XXH_rotl32(h32, 11) * PRIME32_1 ;
p++;
}
h32 ^= h32 >> 15;
h32 *= PRIME32_2;
h32 ^= h32 >> 13;
h32 *= PRIME32_3;
h32 ^= h32 >> 16;
return h32;
}
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unsigned int XXH32 (const void* input, size_t len, unsigned int seed)
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{
#if 0
/* Simple version, good for code maintenance, but unfortunately slow for small inputs */
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XXH32_state_t state;
XXH32_reset(&state, seed);
XXH32_update(&state, input, len);
return XXH32_digest(&state);
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#else
XXH_endianess endian_detected = (XXH_endianess)XXH_CPU_LITTLE_ENDIAN;
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# if !defined(XXH_USELESS_ALIGN_BRANCH)
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if ((((size_t)input) & 3) == 0) /* Input is 4-bytes aligned, leverage the speed benefit */
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{
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
return XXH32_endian_align(input, len, seed, XXH_littleEndian, XXH_aligned);
else
return XXH32_endian_align(input, len, seed, XXH_bigEndian, XXH_aligned);
}
# endif
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
return XXH32_endian_align(input, len, seed, XXH_littleEndian, XXH_unaligned);
else
return XXH32_endian_align(input, len, seed, XXH_bigEndian, XXH_unaligned);
#endif
}
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FORCE_INLINE U64 XXH64_endian_align(const void* input, size_t len, U64 seed, XXH_endianess endian, XXH_alignment align)
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{
const BYTE* p = (const BYTE*)input;
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const BYTE* bEnd = p + len;
U64 h64;
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#define XXH_get64bits(p) XXH_readLE64_align(p, endian, align)
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#ifdef XXH_ACCEPT_NULL_INPUT_POINTER
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if (p==NULL)
{
len=0;
bEnd=p=(const BYTE*)(size_t)32;
}
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#endif
if (len>=32)
{
const BYTE* const limit = bEnd - 32;
U64 v1 = seed + PRIME64_1 + PRIME64_2;
U64 v2 = seed + PRIME64_2;
U64 v3 = seed + 0;
U64 v4 = seed - PRIME64_1;
do
{
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v1 += XXH_get64bits(p) * PRIME64_2;
p+=8;
v1 = XXH_rotl64(v1, 31);
v1 *= PRIME64_1;
v2 += XXH_get64bits(p) * PRIME64_2;
p+=8;
v2 = XXH_rotl64(v2, 31);
v2 *= PRIME64_1;
v3 += XXH_get64bits(p) * PRIME64_2;
p+=8;
v3 = XXH_rotl64(v3, 31);
v3 *= PRIME64_1;
v4 += XXH_get64bits(p) * PRIME64_2;
p+=8;
v4 = XXH_rotl64(v4, 31);
v4 *= PRIME64_1;
}
while (p<=limit);
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h64 = XXH_rotl64(v1, 1) + XXH_rotl64(v2, 7) + XXH_rotl64(v3, 12) + XXH_rotl64(v4, 18);
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v1 *= PRIME64_2;
v1 = XXH_rotl64(v1, 31);
v1 *= PRIME64_1;
h64 ^= v1;
h64 = h64 * PRIME64_1 + PRIME64_4;
v2 *= PRIME64_2;
v2 = XXH_rotl64(v2, 31);
v2 *= PRIME64_1;
h64 ^= v2;
h64 = h64 * PRIME64_1 + PRIME64_4;
v3 *= PRIME64_2;
v3 = XXH_rotl64(v3, 31);
v3 *= PRIME64_1;
h64 ^= v3;
h64 = h64 * PRIME64_1 + PRIME64_4;
v4 *= PRIME64_2;
v4 = XXH_rotl64(v4, 31);
v4 *= PRIME64_1;
h64 ^= v4;
h64 = h64 * PRIME64_1 + PRIME64_4;
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}
else
{
h64 = seed + PRIME64_5;
}
h64 += (U64) len;
while (p+8<=bEnd)
{
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U64 k1 = XXH_get64bits(p);
k1 *= PRIME64_2;
k1 = XXH_rotl64(k1,31);
k1 *= PRIME64_1;
h64 ^= k1;
h64 = XXH_rotl64(h64,27) * PRIME64_1 + PRIME64_4;
p+=8;
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}
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if (p+4<=bEnd)
{
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h64 ^= (U64)(XXH_get32bits(p)) * PRIME64_1;
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h64 = XXH_rotl64(h64, 23) * PRIME64_2 + PRIME64_3;
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p+=4;
}
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while (p<bEnd)
{
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h64 ^= (*p) * PRIME64_5;
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h64 = XXH_rotl64(h64, 11) * PRIME64_1;
p++;
}
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h64 ^= h64 >> 33;
h64 *= PRIME64_2;
h64 ^= h64 >> 29;
h64 *= PRIME64_3;
h64 ^= h64 >> 32;
return h64;
}
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unsigned long long XXH64 (const void* input, size_t len, unsigned long long seed)
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{
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#if 0
/* Simple version, good for code maintenance, but unfortunately slow for small inputs */
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XXH64_state_t state;
XXH64_reset(&state, seed);
XXH64_update(&state, input, len);
return XXH64_digest(&state);
#else
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XXH_endianess endian_detected = (XXH_endianess)XXH_CPU_LITTLE_ENDIAN;
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# if !defined(XXH_USELESS_ALIGN_BRANCH)
if ((((size_t)input) & 7)==0) /* Input is aligned, let's leverage the speed advantage */
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{
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
return XXH64_endian_align(input, len, seed, XXH_littleEndian, XXH_aligned);
else
return XXH64_endian_align(input, len, seed, XXH_bigEndian, XXH_aligned);
}
# endif
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
return XXH64_endian_align(input, len, seed, XXH_littleEndian, XXH_unaligned);
else
return XXH64_endian_align(input, len, seed, XXH_bigEndian, XXH_unaligned);
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#endif
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}
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/****************************************************
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* Advanced Hash Functions
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****************************************************/
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/*** Allocation ***/
typedef struct
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{
U64 total_len;
U32 seed;
U32 v1;
U32 v2;
U32 v3;
U32 v4;
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U32 mem32[4]; /* defined as U32 for alignment */
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U32 memsize;
} XXH_istate32_t;
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typedef struct
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{
U64 total_len;
U64 seed;
U64 v1;
U64 v2;
U64 v3;
U64 v4;
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U64 mem64[4]; /* defined as U64 for alignment */
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U32 memsize;
} XXH_istate64_t;
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XXH32_state_t* XXH32_createState(void)
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{
XXH_STATIC_ASSERT(sizeof(XXH32_state_t) >= sizeof(XXH_istate32_t)); /* A compilation error here means XXH32_state_t is not large enough */
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return (XXH32_state_t*)XXH_malloc(sizeof(XXH32_state_t));
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}
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XXH_errorcode XXH32_freeState(XXH32_state_t* statePtr)
{
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XXH_free(statePtr);
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return XXH_OK;
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}
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XXH64_state_t* XXH64_createState(void)
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{
XXH_STATIC_ASSERT(sizeof(XXH64_state_t) >= sizeof(XXH_istate64_t)); /* A compilation error here means XXH64_state_t is not large enough */
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return (XXH64_state_t*)XXH_malloc(sizeof(XXH64_state_t));
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}
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XXH_errorcode XXH64_freeState(XXH64_state_t* statePtr)
{
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XXH_free(statePtr);
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return XXH_OK;
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}
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/*** Hash feed ***/
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XXH_errorcode XXH32_reset(XXH32_state_t* state_in, unsigned int seed)
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{
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XXH_istate32_t* state = (XXH_istate32_t*) state_in;
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state->seed = seed;
state->v1 = seed + PRIME32_1 + PRIME32_2;
state->v2 = seed + PRIME32_2;
state->v3 = seed + 0;
state->v4 = seed - PRIME32_1;
state->total_len = 0;
state->memsize = 0;
return XXH_OK;
}
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XXH_errorcode XXH64_reset(XXH64_state_t* state_in, unsigned long long seed)
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{
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XXH_istate64_t* state = (XXH_istate64_t*) state_in;
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state->seed = seed;
state->v1 = seed + PRIME64_1 + PRIME64_2;
state->v2 = seed + PRIME64_2;
state->v3 = seed + 0;
state->v4 = seed - PRIME64_1;
state->total_len = 0;
state->memsize = 0;
return XXH_OK;
}
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FORCE_INLINE XXH_errorcode XXH32_update_endian (XXH32_state_t* state_in, const void* input, size_t len, XXH_endianess endian)
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{
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XXH_istate32_t* state = (XXH_istate32_t *) state_in;
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const BYTE* p = (const BYTE*)input;
const BYTE* const bEnd = p + len;
#ifdef XXH_ACCEPT_NULL_INPUT_POINTER
if (input==NULL) return XXH_ERROR;
#endif
state->total_len += len;
if (state->memsize + len < 16) /* fill in tmp buffer */
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{
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XXH_memcpy((BYTE*)(state->mem32) + state->memsize, input, len);
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state->memsize += (U32)len;
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return XXH_OK;
}
if (state->memsize) /* some data left from previous update */
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{
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XXH_memcpy((BYTE*)(state->mem32) + state->memsize, input, 16-state->memsize);
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{
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const U32* p32 = state->mem32;
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state->v1 += XXH_readLE32(p32, endian) * PRIME32_2;
state->v1 = XXH_rotl32(state->v1, 13);
state->v1 *= PRIME32_1;
p32++;
state->v2 += XXH_readLE32(p32, endian) * PRIME32_2;
state->v2 = XXH_rotl32(state->v2, 13);
state->v2 *= PRIME32_1;
p32++;
state->v3 += XXH_readLE32(p32, endian) * PRIME32_2;
state->v3 = XXH_rotl32(state->v3, 13);
state->v3 *= PRIME32_1;
p32++;
state->v4 += XXH_readLE32(p32, endian) * PRIME32_2;
state->v4 = XXH_rotl32(state->v4, 13);
state->v4 *= PRIME32_1;
p32++;
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}
p += 16-state->memsize;
state->memsize = 0;
}
if (p <= bEnd-16)
{
const BYTE* const limit = bEnd - 16;
U32 v1 = state->v1;
U32 v2 = state->v2;
U32 v3 = state->v3;
U32 v4 = state->v4;
do
{
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v1 += XXH_readLE32(p, endian) * PRIME32_2;
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v1 = XXH_rotl32(v1, 13);
v1 *= PRIME32_1;
p+=4;
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v2 += XXH_readLE32(p, endian) * PRIME32_2;
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v2 = XXH_rotl32(v2, 13);
v2 *= PRIME32_1;
p+=4;
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v3 += XXH_readLE32(p, endian) * PRIME32_2;
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v3 = XXH_rotl32(v3, 13);
v3 *= PRIME32_1;
p+=4;
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v4 += XXH_readLE32(p, endian) * PRIME32_2;
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v4 = XXH_rotl32(v4, 13);
v4 *= PRIME32_1;
p+=4;
}
while (p<=limit);
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state->v1 = v1;
state->v2 = v2;
state->v3 = v3;
state->v4 = v4;
}
if (p < bEnd)
{
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XXH_memcpy(state->mem32, p, bEnd-p);
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state->memsize = (int)(bEnd-p);
}
return XXH_OK;
}
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XXH_errorcode XXH32_update (XXH32_state_t* state_in, const void* input, size_t len)
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{
XXH_endianess endian_detected = (XXH_endianess)XXH_CPU_LITTLE_ENDIAN;
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
return XXH32_update_endian(state_in, input, len, XXH_littleEndian);
else
return XXH32_update_endian(state_in, input, len, XXH_bigEndian);
}
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FORCE_INLINE U32 XXH32_digest_endian (const XXH32_state_t* state_in, XXH_endianess endian)
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{
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const XXH_istate32_t* state = (const XXH_istate32_t*) state_in;
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const BYTE * p = (const BYTE*)state->mem32;
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const BYTE* bEnd = (const BYTE*)(state->mem32) + state->memsize;
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U32 h32;
if (state->total_len >= 16)
{
h32 = XXH_rotl32(state->v1, 1) + XXH_rotl32(state->v2, 7) + XXH_rotl32(state->v3, 12) + XXH_rotl32(state->v4, 18);
}
else
{
h32 = state->seed + PRIME32_5;
}
h32 += (U32) state->total_len;
while (p+4<=bEnd)
{
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h32 += XXH_readLE32(p, endian) * PRIME32_3;
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h32 = XXH_rotl32(h32, 17) * PRIME32_4;
p+=4;
}
while (p<bEnd)
{
h32 += (*p) * PRIME32_5;
h32 = XXH_rotl32(h32, 11) * PRIME32_1;
p++;
}
h32 ^= h32 >> 15;
h32 *= PRIME32_2;
h32 ^= h32 >> 13;
h32 *= PRIME32_3;
h32 ^= h32 >> 16;
return h32;
}
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unsigned int XXH32_digest (const XXH32_state_t* state_in)
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{
XXH_endianess endian_detected = (XXH_endianess)XXH_CPU_LITTLE_ENDIAN;
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
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return XXH32_digest_endian(state_in, XXH_littleEndian);
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else
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return XXH32_digest_endian(state_in, XXH_bigEndian);
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}
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FORCE_INLINE XXH_errorcode XXH64_update_endian (XXH64_state_t* state_in, const void* input, size_t len, XXH_endianess endian)
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{
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XXH_istate64_t * state = (XXH_istate64_t *) state_in;
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const BYTE* p = (const BYTE*)input;
const BYTE* const bEnd = p + len;
#ifdef XXH_ACCEPT_NULL_INPUT_POINTER
if (input==NULL) return XXH_ERROR;
#endif
state->total_len += len;
if (state->memsize + len < 32) /* fill in tmp buffer */
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{
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XXH_memcpy(((BYTE*)state->mem64) + state->memsize, input, len);
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state->memsize += (U32)len;
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return XXH_OK;
}
if (state->memsize) /* some data left from previous update */
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{
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XXH_memcpy(((BYTE*)state->mem64) + state->memsize, input, 32-state->memsize);
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{
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const U64* p64 = state->mem64;
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state->v1 += XXH_readLE64(p64, endian) * PRIME64_2;
state->v1 = XXH_rotl64(state->v1, 31);
state->v1 *= PRIME64_1;
p64++;
state->v2 += XXH_readLE64(p64, endian) * PRIME64_2;
state->v2 = XXH_rotl64(state->v2, 31);
state->v2 *= PRIME64_1;
p64++;
state->v3 += XXH_readLE64(p64, endian) * PRIME64_2;
state->v3 = XXH_rotl64(state->v3, 31);
state->v3 *= PRIME64_1;
p64++;
state->v4 += XXH_readLE64(p64, endian) * PRIME64_2;
state->v4 = XXH_rotl64(state->v4, 31);
state->v4 *= PRIME64_1;
p64++;
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}
p += 32-state->memsize;
state->memsize = 0;
}
if (p+32 <= bEnd)
{
const BYTE* const limit = bEnd - 32;
U64 v1 = state->v1;
U64 v2 = state->v2;
U64 v3 = state->v3;
U64 v4 = state->v4;
do
{
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v1 += XXH_readLE64(p, endian) * PRIME64_2;
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v1 = XXH_rotl64(v1, 31);
v1 *= PRIME64_1;
p+=8;
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v2 += XXH_readLE64(p, endian) * PRIME64_2;
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v2 = XXH_rotl64(v2, 31);
v2 *= PRIME64_1;
p+=8;
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v3 += XXH_readLE64(p, endian) * PRIME64_2;
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v3 = XXH_rotl64(v3, 31);
v3 *= PRIME64_1;
p+=8;
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v4 += XXH_readLE64(p, endian) * PRIME64_2;
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v4 = XXH_rotl64(v4, 31);
v4 *= PRIME64_1;
p+=8;
}
while (p<=limit);
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state->v1 = v1;
state->v2 = v2;
state->v3 = v3;
state->v4 = v4;
}
if (p < bEnd)
{
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XXH_memcpy(state->mem64, p, bEnd-p);
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state->memsize = (int)(bEnd-p);
}
return XXH_OK;
}
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XXH_errorcode XXH64_update (XXH64_state_t* state_in, const void* input, size_t len)
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{
XXH_endianess endian_detected = (XXH_endianess)XXH_CPU_LITTLE_ENDIAN;
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
return XXH64_update_endian(state_in, input, len, XXH_littleEndian);
else
return XXH64_update_endian(state_in, input, len, XXH_bigEndian);
}
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FORCE_INLINE U64 XXH64_digest_endian (const XXH64_state_t* state_in, XXH_endianess endian)
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{
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const XXH_istate64_t * state = (const XXH_istate64_t *) state_in;
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const BYTE * p = (const BYTE*)state->mem64;
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const BYTE* bEnd = (const BYTE*)state->mem64 + state->memsize;
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U64 h64;
if (state->total_len >= 32)
{
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U64 v1 = state->v1;
U64 v2 = state->v2;
U64 v3 = state->v3;
U64 v4 = state->v4;
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h64 = XXH_rotl64(v1, 1) + XXH_rotl64(v2, 7) + XXH_rotl64(v3, 12) + XXH_rotl64(v4, 18);
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v1 *= PRIME64_2;
v1 = XXH_rotl64(v1, 31);
v1 *= PRIME64_1;
h64 ^= v1;
h64 = h64*PRIME64_1 + PRIME64_4;
v2 *= PRIME64_2;
v2 = XXH_rotl64(v2, 31);
v2 *= PRIME64_1;
h64 ^= v2;
h64 = h64*PRIME64_1 + PRIME64_4;
v3 *= PRIME64_2;
v3 = XXH_rotl64(v3, 31);
v3 *= PRIME64_1;
h64 ^= v3;
h64 = h64*PRIME64_1 + PRIME64_4;
v4 *= PRIME64_2;
v4 = XXH_rotl64(v4, 31);
v4 *= PRIME64_1;
h64 ^= v4;
h64 = h64*PRIME64_1 + PRIME64_4;
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}
else
{
h64 = state->seed + PRIME64_5;
}
h64 += (U64) state->total_len;
while (p+8<=bEnd)
{
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U64 k1 = XXH_readLE64(p, endian);
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k1 *= PRIME64_2;
k1 = XXH_rotl64(k1,31);
k1 *= PRIME64_1;
h64 ^= k1;
h64 = XXH_rotl64(h64,27) * PRIME64_1 + PRIME64_4;
p+=8;
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}
if (p+4<=bEnd)
{
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h64 ^= (U64)(XXH_readLE32(p, endian)) * PRIME64_1;
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h64 = XXH_rotl64(h64, 23) * PRIME64_2 + PRIME64_3;
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p+=4;
}
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while (p<bEnd)
{
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h64 ^= (*p) * PRIME64_5;
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h64 = XXH_rotl64(h64, 11) * PRIME64_1;
p++;
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}
h64 ^= h64 >> 33;
h64 *= PRIME64_2;
h64 ^= h64 >> 29;
h64 *= PRIME64_3;
h64 ^= h64 >> 32;
return h64;
}
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unsigned long long XXH64_digest (const XXH64_state_t* state_in)
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{
XXH_endianess endian_detected = (XXH_endianess)XXH_CPU_LITTLE_ENDIAN;
if ((endian_detected==XXH_littleEndian) || XXH_FORCE_NATIVE_FORMAT)
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return XXH64_digest_endian(state_in, XXH_littleEndian);
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else
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return XXH64_digest_endian(state_in, XXH_bigEndian);
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}