mirror of
https://github.com/trezor/trezor-firmware.git
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335 lines
12 KiB
C
335 lines
12 KiB
C
/*
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---------------------------------------------------------------------------
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Copyright (c) 1998-2014, Brian Gladman, Worcester, UK. All rights reserved.
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The redistribution and use of this software (with or without changes)
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is allowed without the payment of fees or royalties provided that:
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source code distributions include the above copyright notice, this
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list of conditions and the following disclaimer;
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binary distributions include the above copyright notice, this list
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of conditions and the following disclaimer in their documentation.
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This software is provided 'as is' with no explicit or implied warranties
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in respect of its operation, including, but not limited to, correctness
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and fitness for purpose.
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---------------------------------------------------------------------------
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Issue Date: 18/02/2014
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This header file is an INTERNAL file which supports mode implementation
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*/
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#ifndef _MODE_HDR_H
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#define _MODE_HDR_H
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#include <string.h>
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#include <limits.h>
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#include "brg_endian.h"
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/* This define sets the units in which buffers are processed. This code
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can provide significant speed gains if buffers can be processed in
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32 or 64 bit chunks rather than in bytes. This define sets the units
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in which buffers will be accessed if possible
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*/
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#if !defined( UNIT_BITS )
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# if PLATFORM_BYTE_ORDER == IS_BIG_ENDIAN
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# if 0
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# define UNIT_BITS 32
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# elif 1
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# define UNIT_BITS 64
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# endif
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# elif defined( _WIN64 )
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# define UNIT_BITS 64
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# else
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# define UNIT_BITS 32
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# endif
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#endif
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#if UNIT_BITS == 64 && !defined( NEED_UINT_64T )
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# define NEED_UINT_64T
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#endif
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#include <stdint.h>
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#define UI_TYPE(size) uint##size##_t
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#define UNIT_TYPEDEF(x,size) typedef UI_TYPE(size) x
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#define BUFR_TYPEDEF(x,size,bsize) typedef UI_TYPE(size) x[bsize / (size >> 3)]
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#define UNIT_CAST(x,size) ((UI_TYPE(size) )(x))
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#define UPTR_CAST(x,size) ((UI_TYPE(size)*)(x))
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/* Use of inlines is preferred but code blocks can also be expanded inline
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using 'defines'. But the latter approach will typically generate a LOT
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of code and is not recommended.
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*/
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#if 1 && !defined( USE_INLINING )
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# define USE_INLINING
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#endif
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#if defined( _MSC_VER )
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# if _MSC_VER >= 1400
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# include <stdlib.h>
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# include <intrin.h>
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# pragma intrinsic(memset)
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# pragma intrinsic(memcpy)
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# define rotl32 _rotl
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# define rotr32 _rotr
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# define rotl64 _rotl64
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# define rotr64 _rotl64
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# define bswap_16(x) _byteswap_ushort(x)
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# define bswap_32(x) _byteswap_ulong(x)
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# define bswap_64(x) _byteswap_uint64(x)
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# else
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# define rotl32 _lrotl
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# define rotr32 _lrotr
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# endif
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#endif
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#if defined( USE_INLINING )
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# if defined( _MSC_VER )
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# define mh_decl __inline
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# elif defined( __GNUC__ ) || defined( __GNU_LIBRARY__ )
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# define mh_decl static inline
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# else
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# define mh_decl static
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# endif
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#endif
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#if defined(__cplusplus)
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extern "C" {
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#endif
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#define UI8_PTR(x) UPTR_CAST(x, 8)
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#define UI16_PTR(x) UPTR_CAST(x, 16)
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#define UI32_PTR(x) UPTR_CAST(x, 32)
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#define UI64_PTR(x) UPTR_CAST(x, 64)
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#define UNIT_PTR(x) UPTR_CAST(x, UNIT_BITS)
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#define UI8_VAL(x) UNIT_CAST(x, 8)
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#define UI16_VAL(x) UNIT_CAST(x, 16)
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#define UI32_VAL(x) UNIT_CAST(x, 32)
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#define UI64_VAL(x) UNIT_CAST(x, 64)
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#define UNIT_VAL(x) UNIT_CAST(x, UNIT_BITS)
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#define BUF_INC (UNIT_BITS >> 3)
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#define BUF_ADRMASK ((UNIT_BITS >> 3) - 1)
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#define rep2_u2(f,r,x) f( 0,r,x); f( 1,r,x)
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#define rep2_u4(f,r,x) f( 0,r,x); f( 1,r,x); f( 2,r,x); f( 3,r,x)
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#define rep2_u16(f,r,x) f( 0,r,x); f( 1,r,x); f( 2,r,x); f( 3,r,x); \
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f( 4,r,x); f( 5,r,x); f( 6,r,x); f( 7,r,x); \
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f( 8,r,x); f( 9,r,x); f(10,r,x); f(11,r,x); \
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f(12,r,x); f(13,r,x); f(14,r,x); f(15,r,x)
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#define rep2_d2(f,r,x) f( 1,r,x); f( 0,r,x)
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#define rep2_d4(f,r,x) f( 3,r,x); f( 2,r,x); f( 1,r,x); f( 0,r,x)
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#define rep2_d16(f,r,x) f(15,r,x); f(14,r,x); f(13,r,x); f(12,r,x); \
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f(11,r,x); f(10,r,x); f( 9,r,x); f( 8,r,x); \
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f( 7,r,x); f( 6,r,x); f( 5,r,x); f( 4,r,x); \
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f( 3,r,x); f( 2,r,x); f( 1,r,x); f( 0,r,x)
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#define rep3_u2(f,r,x,y,c) f( 0,r,x,y,c); f( 1,r,x,y,c)
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#define rep3_u4(f,r,x,y,c) f( 0,r,x,y,c); f( 1,r,x,y,c); f( 2,r,x,y,c); f( 3,r,x,y,c)
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#define rep3_u16(f,r,x,y,c) f( 0,r,x,y,c); f( 1,r,x,y,c); f( 2,r,x,y,c); f( 3,r,x,y,c); \
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f( 4,r,x,y,c); f( 5,r,x,y,c); f( 6,r,x,y,c); f( 7,r,x,y,c); \
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f( 8,r,x,y,c); f( 9,r,x,y,c); f(10,r,x,y,c); f(11,r,x,y,c); \
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f(12,r,x,y,c); f(13,r,x,y,c); f(14,r,x,y,c); f(15,r,x,y,c)
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#define rep3_d2(f,r,x,y,c) f( 1,r,x,y,c); f( 0,r,x,y,c)
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#define rep3_d4(f,r,x,y,c) f( 3,r,x,y,c); f( 2,r,x,y,c); f( 1,r,x,y,c); f( 0,r,x,y,c)
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#define rep3_d16(f,r,x,y,c) f(15,r,x,y,c); f(14,r,x,y,c); f(13,r,x,y,c); f(12,r,x,y,c); \
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f(11,r,x,y,c); f(10,r,x,y,c); f( 9,r,x,y,c); f( 8,r,x,y,c); \
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f( 7,r,x,y,c); f( 6,r,x,y,c); f( 5,r,x,y,c); f( 4,r,x,y,c); \
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f( 3,r,x,y,c); f( 2,r,x,y,c); f( 1,r,x,y,c); f( 0,r,x,y,c)
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/* function pointers might be used for fast XOR operations */
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typedef void (*xor_function)(void* r, const void* p, const void* q);
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/* left and right rotates on 32 and 64 bit variables */
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#if !defined( rotl32 ) /* NOTE: 0 <= n <= 32 ASSUMED */
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mh_decl uint32_t rotl32(uint32_t x, int n)
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{
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return (((x) << n) | ((x) >> (32 - n)));
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}
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#endif
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#if !defined( rotr32 ) /* NOTE: 0 <= n <= 32 ASSUMED */
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mh_decl uint32_t rotr32(uint32_t x, int n)
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{
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return (((x) >> n) | ((x) << (32 - n)));
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}
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#endif
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#if ( UNIT_BITS == 64 ) && !defined( rotl64 ) /* NOTE: 0 <= n <= 64 ASSUMED */
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mh_decl uint64_t rotl64(uint64_t x, int n)
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{
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return (((x) << n) | ((x) >> (64 - n)));
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}
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#endif
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#if ( UNIT_BITS == 64 ) && !defined( rotr64 ) /* NOTE: 0 <= n <= 64 ASSUMED */
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mh_decl uint64_t rotr64(uint64_t x, int n)
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{
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return (((x) >> n) | ((x) << (64 - n)));
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}
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#endif
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/* byte order inversions for 16, 32 and 64 bit variables */
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#if !defined(bswap_16)
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mh_decl uint16_t bswap_16(uint16_t x)
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{
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return (uint16_t)((x >> 8) | (x << 8));
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}
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#endif
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#if !defined(bswap_32)
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mh_decl uint32_t bswap_32(uint32_t x)
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{
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return ((rotr32((x), 24) & 0x00ff00ff) | (rotr32((x), 8) & 0xff00ff00));
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}
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#endif
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#if ( UNIT_BITS == 64 ) && !defined(bswap_64)
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mh_decl uint64_t bswap_64(uint64_t x)
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{
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return bswap_32((uint32_t)(x >> 32)) | ((uint64_t)bswap_32((uint32_t)x) << 32);
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}
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#endif
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/* support for fast aligned buffer move, xor and byte swap operations -
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source and destination buffers for move and xor operations must not
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overlap, those for byte order revesal must either not overlap or
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must be identical
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*/
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#define f_copy(n,p,q) p[n] = q[n]
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#define f_xor(n,r,p,q,c) r[n] = c(p[n] ^ q[n])
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mh_decl void copy_block(void* p, const void* q)
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{
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memcpy(p, q, 16);
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}
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mh_decl void copy_block_aligned(void *p, const void *q)
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{
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#if UNIT_BITS == 8
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memcpy(p, q, 16);
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#elif UNIT_BITS == 32
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rep2_u4(f_copy,UNIT_PTR(p),UNIT_PTR(q));
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#else
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rep2_u2(f_copy,UNIT_PTR(p),UNIT_PTR(q));
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#endif
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}
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mh_decl void xor_block(void *r, const void* p, const void* q)
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{
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rep3_u16(f_xor, UI8_PTR(r), UI8_PTR(p), UI8_PTR(q), UI8_VAL);
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}
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mh_decl void xor_block_aligned(void *r, const void *p, const void *q)
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{
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#if UNIT_BITS == 8
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rep3_u16(f_xor, UNIT_PTR(r), UNIT_PTR(p), UNIT_PTR(q), UNIT_VAL);
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#elif UNIT_BITS == 32
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rep3_u4(f_xor, UNIT_PTR(r), UNIT_PTR(p), UNIT_PTR(q), UNIT_VAL);
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#else
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rep3_u2(f_xor, UNIT_PTR(r), UNIT_PTR(p), UNIT_PTR(q), UNIT_VAL);
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#endif
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}
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/* byte swap within 32-bit words in a 16 byte block; don't move 32-bit words */
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mh_decl void bswap32_block(void *d, const void* s)
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{
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#if UNIT_BITS == 8
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uint8_t t = 0;
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t = UNIT_PTR(s)[ 0]; UNIT_PTR(d)[ 0] = UNIT_PTR(s)[ 3]; UNIT_PTR(d)[ 3] = t;
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t = UNIT_PTR(s)[ 1]; UNIT_PTR(d)[ 1] = UNIT_PTR(s)[ 2]; UNIT_PTR(d)[ 2] = t;
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t = UNIT_PTR(s)[ 4]; UNIT_PTR(d)[ 4] = UNIT_PTR(s)[ 7]; UNIT_PTR(d)[ 7] = t;
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t = UNIT_PTR(s)[ 5]; UNIT_PTR(d)[ 5] = UNIT_PTR(s)[ 6]; UNIT_PTR(d) [6] = t;
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t = UNIT_PTR(s)[ 8]; UNIT_PTR(d)[ 8] = UNIT_PTR(s)[11]; UNIT_PTR(d)[12] = t;
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t = UNIT_PTR(s)[ 9]; UNIT_PTR(d)[ 9] = UNIT_PTR(s)[10]; UNIT_PTR(d)[10] = t;
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t = UNIT_PTR(s)[12]; UNIT_PTR(d)[12] = UNIT_PTR(s)[15]; UNIT_PTR(d)[15] = t;
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t = UNIT_PTR(s)[13]; UNIT_PTR(d)[ 3] = UNIT_PTR(s)[14]; UNIT_PTR(d)[14] = t;
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#elif UNIT_BITS == 32
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UNIT_PTR(d)[0] = bswap_32(UNIT_PTR(s)[0]); UNIT_PTR(d)[1] = bswap_32(UNIT_PTR(s)[1]);
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UNIT_PTR(d)[2] = bswap_32(UNIT_PTR(s)[2]); UNIT_PTR(d)[3] = bswap_32(UNIT_PTR(s)[3]);
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#else
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UI32_PTR(d)[0] = bswap_32(UI32_PTR(s)[0]); UI32_PTR(d)[1] = bswap_32(UI32_PTR(s)[1]);
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UI32_PTR(d)[2] = bswap_32(UI32_PTR(s)[2]); UI32_PTR(d)[3] = bswap_32(UI32_PTR(s)[3]);
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#endif
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}
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/* byte swap within 64-bit words in a 16 byte block; don't move 64-bit words */
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mh_decl void bswap64_block(void *d, const void* s)
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{
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#if UNIT_BITS == 8
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uint8_t t = 0;
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t = UNIT_PTR(s)[ 0]; UNIT_PTR(d)[ 0] = UNIT_PTR(s)[ 7]; UNIT_PTR(d)[ 7] = t;
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t = UNIT_PTR(s)[ 1]; UNIT_PTR(d)[ 1] = UNIT_PTR(s)[ 6]; UNIT_PTR(d)[ 6] = t;
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t = UNIT_PTR(s)[ 2]; UNIT_PTR(d)[ 2] = UNIT_PTR(s)[ 5]; UNIT_PTR(d)[ 5] = t;
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t = UNIT_PTR(s)[ 3]; UNIT_PTR(d)[ 3] = UNIT_PTR(s)[ 3]; UNIT_PTR(d) [3] = t;
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t = UNIT_PTR(s)[ 8]; UNIT_PTR(d)[ 8] = UNIT_PTR(s)[15]; UNIT_PTR(d)[15] = t;
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t = UNIT_PTR(s)[ 9]; UNIT_PTR(d)[ 9] = UNIT_PTR(s)[14]; UNIT_PTR(d)[14] = t;
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t = UNIT_PTR(s)[10]; UNIT_PTR(d)[10] = UNIT_PTR(s)[13]; UNIT_PTR(d)[13] = t;
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t = UNIT_PTR(s)[11]; UNIT_PTR(d)[11] = UNIT_PTR(s)[12]; UNIT_PTR(d)[12] = t;
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#elif UNIT_BITS == 32
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uint32_t t = 0;
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t = bswap_32(UNIT_PTR(s)[0]); UNIT_PTR(d)[0] = bswap_32(UNIT_PTR(s)[1]); UNIT_PTR(d)[1] = t;
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t = bswap_32(UNIT_PTR(s)[2]); UNIT_PTR(d)[2] = bswap_32(UNIT_PTR(s)[2]); UNIT_PTR(d)[3] = t;
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#else
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UNIT_PTR(d)[0] = bswap_64(UNIT_PTR(s)[0]); UNIT_PTR(d)[1] = bswap_64(UNIT_PTR(s)[1]);
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#endif
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}
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mh_decl void bswap128_block(void *d, const void* s)
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{
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#if UNIT_BITS == 8
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uint8_t t = 0;
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t = UNIT_PTR(s)[0]; UNIT_PTR(d)[0] = UNIT_PTR(s)[15]; UNIT_PTR(d)[15] = t;
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t = UNIT_PTR(s)[1]; UNIT_PTR(d)[1] = UNIT_PTR(s)[14]; UNIT_PTR(d)[14] = t;
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t = UNIT_PTR(s)[2]; UNIT_PTR(d)[2] = UNIT_PTR(s)[13]; UNIT_PTR(d)[13] = t;
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t = UNIT_PTR(s)[3]; UNIT_PTR(d)[3] = UNIT_PTR(s)[12]; UNIT_PTR(d)[12] = t;
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t = UNIT_PTR(s)[4]; UNIT_PTR(d)[4] = UNIT_PTR(s)[11]; UNIT_PTR(d)[11] = t;
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t = UNIT_PTR(s)[5]; UNIT_PTR(d)[5] = UNIT_PTR(s)[10]; UNIT_PTR(d)[10] = t;
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t = UNIT_PTR(s)[6]; UNIT_PTR(d)[6] = UNIT_PTR(s)[ 9]; UNIT_PTR(d)[ 9] = t;
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t = UNIT_PTR(s)[7]; UNIT_PTR(d)[7] = UNIT_PTR(s)[ 8]; UNIT_PTR(d)[ 8] = t;
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#elif UNIT_BITS == 32
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uint32_t t = 0;
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t = bswap_32(UNIT_PTR(s)[0]); UNIT_PTR(d)[0] = bswap_32(UNIT_PTR(s)[3]); UNIT_PTR(d)[3] = t;
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t = bswap_32(UNIT_PTR(s)[1]); UNIT_PTR(d)[1] = bswap_32(UNIT_PTR(s)[2]); UNIT_PTR(d)[2] = t;
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#else
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uint64_t t = 0;
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t = bswap_64(UNIT_PTR(s)[0]); UNIT_PTR(d)[0] = bswap_64(UNIT_PTR(s)[1]); UNIT_PTR(d)[1] = t;
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#endif
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}
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/* platform byte order to big or little endian order for 16, 32 and 64 bit variables */
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#if PLATFORM_BYTE_ORDER == IS_BIG_ENDIAN
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# define uint16_t_to_le(x) (x) = bswap_16((x))
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# define uint32_t_to_le(x) (x) = bswap_32((x))
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# define uint64_t_to_le(x) (x) = bswap_64((x))
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# define uint16_t_to_be(x)
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# define uint32_t_to_be(x)
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# define uint64_t_to_be(x)
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#else
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# define uint16_t_to_le(x)
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# define uint32_t_to_le(x)
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# define uint64_t_to_le(x)
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# define uint16_t_to_be(x) (x) = bswap_16((x))
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# define uint32_t_to_be(x) (x) = bswap_32((x))
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# define uint64_t_to_be(x) (x) = bswap_64((x))
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#endif
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#if defined(__cplusplus)
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}
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#endif
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#endif
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