src/liblzma/lz/lz_encoder_hash.h - jrn/xz - Git at Google

 ///////////////////////////////////////////////////////////////////////////////
 //
 /// \file       lz_encoder_hash.h
 /// \brief      Hash macros for match finders
 //
 //  Author:     Igor Pavlov
 //
 //  This file has been put into the public domain.
 //  You can do whatever you want with this file.
 //
 ///////////////////////////////////////////////////////////////////////////////

 #ifndef LZMA_LZ_ENCODER_HASH_H
 #define LZMA_LZ_ENCODER_HASH_H

 #if defined(WORDS_BIGENDIAN) && !defined(HAVE_SMALL)
 	// This is to make liblzma produce the same output on big endian
 	// systems that it does on little endian systems. lz_encoder.c
 	// takes care of including the actual table.
 	extern const uint32_t lzma_lz_hash_table[256];
 #	define hash_table lzma_lz_hash_table
 #else
 #	include "check.h"
 #	define hash_table lzma_crc32_table[0]
 #endif

 #define HASH_2_SIZE (UINT32_C(1) << 10)
 #define HASH_3_SIZE (UINT32_C(1) << 16)
 #define HASH_4_SIZE (UINT32_C(1) << 20)

 #define HASH_2_MASK (HASH_2_SIZE - 1)
 #define HASH_3_MASK (HASH_3_SIZE - 1)
 #define HASH_4_MASK (HASH_4_SIZE - 1)

 #define FIX_3_HASH_SIZE (HASH_2_SIZE)
 #define FIX_4_HASH_SIZE (HASH_2_SIZE + HASH_3_SIZE)
 #define FIX_5_HASH_SIZE (HASH_2_SIZE + HASH_3_SIZE + HASH_4_SIZE)

 // Endianness doesn't matter in hash_2_calc() (no effect on the output).
 #ifdef TUKLIB_FAST_UNALIGNED_ACCESS
 #	define hash_2_calc() \
 		const uint32_t hash_value = *(const uint16_t *)(cur)
 #else
 #	define hash_2_calc() \
 		const uint32_t hash_value \
 			= (uint32_t)(cur[0]) | ((uint32_t)(cur[1]) << 8)
 #endif

 #define hash_3_calc() \
 	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
 	const uint32_t hash_2_value = temp & HASH_2_MASK; \
 	const uint32_t hash_value \
 			= (temp ^ ((uint32_t)(cur[2]) << 8)) & mf->hash_mask

 #define hash_4_calc() \
 	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
 	const uint32_t hash_2_value = temp & HASH_2_MASK; \
 	const uint32_t hash_3_value \
 			= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK; \
 	const uint32_t hash_value = (temp ^ ((uint32_t)(cur[2]) << 8) \
 			^ (hash_table[cur[3]] << 5)) & mf->hash_mask


 // The following are not currently used.

 #define hash_5_calc() \
 	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
 	const uint32_t hash_2_value = temp & HASH_2_MASK; \
 	const uint32_t hash_3_value \
 			= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK; \
 	uint32_t hash_4_value = (temp ^ ((uint32_t)(cur[2]) << 8) ^ \
 			^ hash_table[cur[3]] << 5); \
 	const uint32_t hash_value \
 			= (hash_4_value ^ (hash_table[cur[4]] << 3)) \
 				& mf->hash_mask; \
 	hash_4_value &= HASH_4_MASK

 /*
 #define hash_zip_calc() \
 	const uint32_t hash_value \
 			= (((uint32_t)(cur[0]) | ((uint32_t)(cur[1]) << 8)) \
 				^ hash_table[cur[2]]) & 0xFFFF
 */

 #define hash_zip_calc() \
 	const uint32_t hash_value \
 			= (((uint32_t)(cur[2]) | ((uint32_t)(cur[0]) << 8)) \
 				^ hash_table[cur[1]]) & 0xFFFF

 #define mt_hash_2_calc() \
 	const uint32_t hash_2_value \
 			= (hash_table[cur[0]] ^ cur[1]) & HASH_2_MASK

 #define mt_hash_3_calc() \
 	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
 	const uint32_t hash_2_value = temp & HASH_2_MASK; \
 	const uint32_t hash_3_value \
 			= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK

 #define mt_hash_4_calc() \
 	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
 	const uint32_t hash_2_value = temp & HASH_2_MASK; \
 	const uint32_t hash_3_value \
 			= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK; \
 	const uint32_t hash_4_value = (temp ^ ((uint32_t)(cur[2]) << 8) ^ \
 			(hash_table[cur[3]] << 5)) & HASH_4_MASK

 #endif
	///////////////////////////////////////////////////////////////////////////////
	//
	/// \file lz_encoder_hash.h
	/// \brief Hash macros for match finders
	//
	// Author: Igor Pavlov
	//
	// This file has been put into the public domain.
	// You can do whatever you want with this file.
	//
	///////////////////////////////////////////////////////////////////////////////

	#ifndef LZMA_LZ_ENCODER_HASH_H
	#define LZMA_LZ_ENCODER_HASH_H

	#if defined(WORDS_BIGENDIAN) && !defined(HAVE_SMALL)
	// This is to make liblzma produce the same output on big endian
	// systems that it does on little endian systems. lz_encoder.c
	// takes care of including the actual table.
	extern const uint32_t lzma_lz_hash_table[256];
	# define hash_table lzma_lz_hash_table
	#else
	# include "check.h"
	# define hash_table lzma_crc32_table[0]
	#endif

	#define HASH_2_SIZE (UINT32_C(1) << 10)
	#define HASH_3_SIZE (UINT32_C(1) << 16)
	#define HASH_4_SIZE (UINT32_C(1) << 20)

	#define HASH_2_MASK (HASH_2_SIZE - 1)
	#define HASH_3_MASK (HASH_3_SIZE - 1)
	#define HASH_4_MASK (HASH_4_SIZE - 1)

	#define FIX_3_HASH_SIZE (HASH_2_SIZE)
	#define FIX_4_HASH_SIZE (HASH_2_SIZE + HASH_3_SIZE)
	#define FIX_5_HASH_SIZE (HASH_2_SIZE + HASH_3_SIZE + HASH_4_SIZE)

	// Endianness doesn't matter in hash_2_calc() (no effect on the output).
	#ifdef TUKLIB_FAST_UNALIGNED_ACCESS
	# define hash_2_calc() \
	const uint32_t hash_value = (const uint16_t )(cur)
	#else
	# define hash_2_calc() \
	const uint32_t hash_value \
	= (uint32_t)(cur[0]) \| ((uint32_t)(cur[1]) << 8)
	#endif

	#define hash_3_calc() \
	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
	const uint32_t hash_2_value = temp & HASH_2_MASK; \
	const uint32_t hash_value \
	= (temp ^ ((uint32_t)(cur[2]) << 8)) & mf->hash_mask

	#define hash_4_calc() \
	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
	const uint32_t hash_2_value = temp & HASH_2_MASK; \
	const uint32_t hash_3_value \
	= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK; \
	const uint32_t hash_value = (temp ^ ((uint32_t)(cur[2]) << 8) \
	^ (hash_table[cur[3]] << 5)) & mf->hash_mask


	// The following are not currently used.

	#define hash_5_calc() \
	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
	const uint32_t hash_2_value = temp & HASH_2_MASK; \
	const uint32_t hash_3_value \
	= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK; \
	uint32_t hash_4_value = (temp ^ ((uint32_t)(cur[2]) << 8) ^ \
	^ hash_table[cur[3]] << 5); \
	const uint32_t hash_value \
	= (hash_4_value ^ (hash_table[cur[4]] << 3)) \
	& mf->hash_mask; \
	hash_4_value &= HASH_4_MASK

	/*
	#define hash_zip_calc() \
	const uint32_t hash_value \
	= (((uint32_t)(cur[0]) \| ((uint32_t)(cur[1]) << 8)) \
	^ hash_table[cur[2]]) & 0xFFFF
	*/

	#define hash_zip_calc() \
	const uint32_t hash_value \
	= (((uint32_t)(cur[2]) \| ((uint32_t)(cur[0]) << 8)) \
	^ hash_table[cur[1]]) & 0xFFFF

	#define mt_hash_2_calc() \
	const uint32_t hash_2_value \
	= (hash_table[cur[0]] ^ cur[1]) & HASH_2_MASK

	#define mt_hash_3_calc() \
	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
	const uint32_t hash_2_value = temp & HASH_2_MASK; \
	const uint32_t hash_3_value \
	= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK

	#define mt_hash_4_calc() \
	const uint32_t temp = hash_table[cur[0]] ^ cur[1]; \
	const uint32_t hash_2_value = temp & HASH_2_MASK; \
	const uint32_t hash_3_value \
	= (temp ^ ((uint32_t)(cur[2]) << 8)) & HASH_3_MASK; \
	const uint32_t hash_4_value = (temp ^ ((uint32_t)(cur[2]) << 8) ^ \
	(hash_table[cur[3]] << 5)) & HASH_4_MASK

	#endif