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837 lines
27 KiB
C++
837 lines
27 KiB
C++
/*
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-------------------------------------------------------------------------
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Copyright (c) 2001, Dr Brian Gladman < >, Worcester, UK.
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All rights reserved.
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LICENSE TERMS
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The free distribution and use of this software in both source and binary
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form is allowed (with or without changes) provided that:
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1. distributions of this source code include the above copyright
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notice, this list of conditions and the following disclaimer;
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2. distributions in binary form include the above copyright
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notice, this list of conditions and the following disclaimer
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in the documentation and/or other associated materials;
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3. the copyright holder's name is not used to endorse products
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built using this software without specific written permission.
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DISCLAIMER
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This software is provided 'as is' with no explicit or implied warranties
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in respect of its properties, including, but not limited to, correctness
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and fitness for purpose.
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-------------------------------------------------------------------------
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Issue Date: 29/07/2002
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This file contains the compilation options for AES (Rijndael) and code
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that is common across encryption, key scheduling and table generation.
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OPERATION
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These source code files implement the AES algorithm Rijndael designed by
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Joan Daemen and Vincent Rijmen. The version in aes.c is designed for
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block and key sizes of 128, 192 and 256 bits (16, 24 and 32 bytes) while
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that in aespp.c provides for block and keys sizes of 128, 160, 192, 224
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and 256 bits (16, 20, 24, 28 and 32 bytes). This file is a common header
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file for these two implementations and for aesref.c, which is a reference
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implementation.
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This version is designed for flexibility and speed using operations on
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32-bit words rather than operations on bytes. It provides aes_both fixed
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and dynamic block and key lengths and can also run with either big or
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little endian internal byte order (see aes.h). It inputs block and key
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lengths in bytes with the legal values being 16, 24 and 32 for aes.c and
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16, 20, 24, 28 and 32 for aespp.c
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THE CIPHER INTERFACE
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aes_08t (an unsigned 8-bit type)
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aes_32t (an unsigned 32-bit type)
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aes_fret (a signed 16 bit type for function return values)
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aes_good (value != 0, a good return)
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aes_bad (value == 0, an error return)
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struct aes_ctx (structure for the cipher encryption context)
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struct aes_ctx (structure for the cipher decryption context)
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aes_rval the function return type (aes_fret if not DLL)
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C subroutine calls:
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aes_rval aes_blk_len(unsigned int blen, aes_ctx cx[1]);
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aes_rval aes_enc_key(const unsigned char in_key[], unsigned int klen, aes_ctx cx[1]);
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aes_rval aes_enc_blk(const unsigned char in_blk[], unsigned char out_blk[], const aes_ctx cx[1]);
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aes_rval aes_dec_len(unsigned int blen, aes_ctx cx[1]);
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aes_rval aes_dec_key(const unsigned char in_key[], unsigned int klen, aes_ctx cx[1]);
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aes_rval aes_dec_blk(const unsigned char in_blk[], unsigned char out_blk[], const aes_ctx cx[1]);
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IMPORTANT NOTE: If you are using this C interface and your compiler does
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not set the memory used for objects to zero before use, you will need to
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ensure that cx.s_flg is set to zero before using these subroutine calls.
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C++ aes class subroutines:
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class AESclass for encryption
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class AESclass for decryption
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aes_rval len(unsigned int blen = 16);
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aes_rval key(const unsigned char in_key[], unsigned int klen);
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aes_rval blk(const unsigned char in_blk[], unsigned char out_blk[]);
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aes_rval len(unsigned int blen = 16);
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aes_rval key(const unsigned char in_key[], unsigned int klen);
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aes_rval blk(const unsigned char in_blk[], unsigned char out_blk[]);
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The block length inputs to set_block and set_key are in numbers of
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BYTES, not bits. The calls to subroutines must be made in the above
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order but multiple calls can be made without repeating earlier calls
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if their parameters have not changed. If the cipher block length is
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variable but set_blk has not been called before cipher operations a
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value of 16 is assumed (that is, the AES block size). In contrast to
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earlier versions the block and key length parameters are now checked
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for correctness and the encryption and decryption routines check to
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ensure that an appropriate key has been set before they are called.
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COMPILATION
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The files used to provide AES (Rijndael) are
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a. aes.h for the definitions needed for use in C.
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b. aescpp.h for the definitions needed for use in C++.
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c. aesopt.h for setting compilation options (also includes common
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code).
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d. aescrypt.c for encryption and decrytpion, or
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e. aescrypt.asm for encryption and decryption using assembler code.
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f. aeskey.c for key scheduling.
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g. aestab.c for table loading or generation.
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The assembler code uses the NASM assembler. The above files provice
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block and key lengths of 16, 24 and 32 bytes (128, 192 and 256 bits).
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If aescrypp.c and aeskeypp.c are used instead of aescrypt.c and
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aeskey.c respectively, the block and key lengths can then be 16, 20,
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24, 28 or 32 bytes. However this code has not been optimised to the
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same extent and is hence slower (esepcially for the AES block size
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of 16 bytes).
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To compile AES (Rijndael) for use in C code use aes.h and exclude
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the AES_DLL define in aes.h
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To compile AES (Rijndael) for use in in C++ code use aescpp.h and
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exclude the AES_DLL define in aes.h
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To compile AES (Rijndael) in C as a Dynamic Link Library DLL) use
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aes.h, include the AES_DLL define and compile the DLL. If using
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the test files to test the DLL, exclude aes.c from the test build
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project and compile it with the same defines as used for the DLL
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(ensure that the DLL path is correct)
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CONFIGURATION OPTIONS (here and in aes.h)
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a. define BLOCK_SIZE in aes.h to set the cipher block size (16, 24
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or 32 for the standard code, or 16, 20, 24, 28 or 32 for the
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extended code) or leave this undefined for dynamically variable
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block size (this will result in much slower code).
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b. set AES_DLL in aes.h if AES (Rijndael) is to be compiled as a DLL
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c. You may need to set PLATFORM_BYTE_ORDER to define the byte order.
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d. If you want the code to run in a specific internal byte order, then
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INTERNAL_BYTE_ORDER must be set accordingly.
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e. set other configuration options decribed below.
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*/
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#ifndef _AESOPT_H
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#define _AESOPT_H
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/* START OF CONFIGURATION OPTIONS
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USE OF DEFINES
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Later in this section there are a number of defines that control the
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operation of the code. In each section, the purpose of each define is
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explained so that the relevant form can be included or excluded by
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setting either 1's or 0's respectively on the branches of the related
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#if clauses.
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*/
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/* 1. PLATFORM SPECIFIC INCLUDES */
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#include "aes.h"
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#define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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/*
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#if defined( __CRYPTLIB__ ) && !defined( INC_ALL ) && !defined( INC_CHILD )
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#include "crypt/aes.h"
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#else
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#include "aes.h"
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#endif
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#if defined(__GNUC__) || defined(__GNU_LIBRARY__)
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//# include <endian.h>
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//# include <byteswap.h>
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#elif defined(__CRYPTLIB__)
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# if defined( INC_ALL )
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# include "crypt.h"
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# elif defined( INC_CHILD )
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# include "../crypt.h"
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# else
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# include "crypt.h"
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# endif
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# if defined(DATA_LITTLEENDIAN)
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# define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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# else
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# define PLATFORM_BYTE_ORDER AES_BIG_ENDIAN
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# endif
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#elif defined(_MSC_VER)
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# include <stdlib.h>
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#elif !defined(WIN32)
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# include <stdlib.h>
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# if !defined (_ENDIAN_H)
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# include <sys/param.h>
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# else
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# include _ENDIAN_H
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# endif
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#endif
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*/
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/* 2. BYTE ORDER IN 32-BIT WORDS
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To obtain the highest speed on processors with 32-bit words, this code
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needs to determine the order in which bytes are packed into such words.
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The following block of code is an attempt to capture the most obvious
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ways in which various environemnts define byte order. It may well fail,
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in which case the definitions will need to be set by editing at the
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points marked **** EDIT HERE IF NECESSARY **** below.
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*/
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#define AES_LITTLE_ENDIAN 1234 /* byte 0 is least significant (i386) */
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#define AES_BIG_ENDIAN 4321 /* byte 0 is most significant (mc68k) */
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#if !defined(PLATFORM_BYTE_ORDER)
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#if defined(LITTLE_ENDIAN) || defined(BIG_ENDIAN)
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# if defined(LITTLE_ENDIAN) && defined(BIG_ENDIAN)
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# if defined(BYTE_ORDER)
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# if (BYTE_ORDER == LITTLE_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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# elif (BYTE_ORDER == BIG_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_BIG_ENDIAN
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# endif
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# endif
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# elif defined(LITTLE_ENDIAN) && !defined(BIG_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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# elif !defined(LITTLE_ENDIAN) && defined(BIG_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_BIG_ENDIAN
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# endif
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#elif defined(_LITTLE_ENDIAN) || defined(_BIG_ENDIAN)
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# if defined(_LITTLE_ENDIAN) && defined(_BIG_ENDIAN)
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# if defined(_BYTE_ORDER)
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# if (_BYTE_ORDER == _LITTLE_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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# elif (_BYTE_ORDER == _BIG_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_BIG_ENDIAN
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# endif
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# endif
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# elif defined(_LITTLE_ENDIAN) && !defined(_BIG_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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# elif !defined(_LITTLE_ENDIAN) && defined(_BIG_ENDIAN)
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# define PLATFORM_BYTE_ORDER AES_BIG_ENDIAN
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# endif
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#elif 0 /* **** EDIT HERE IF NECESSARY **** */
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#define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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#elif 0 /* **** EDIT HERE IF NECESSARY **** */
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#define PLATFORM_BYTE_ORDER AES_BIG_ENDIAN
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/*
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#elif (('1234' >> 24) == '1')
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# define PLATFORM_BYTE_ORDER AES_LITTLE_ENDIAN
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#elif (('4321' >> 24) == '1')
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# define PLATFORM_BYTE_ORDER AES_BIG_ENDIAN
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*/
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#endif
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#endif
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#if !defined(PLATFORM_BYTE_ORDER)
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# error Please set undetermined byte order (lines 233 or 235 of aesopt.h).
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#endif
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/* 3. ASSEMBLER SUPPORT
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If the assembler code is used for encryption and decryption this file only
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provides key scheduling so the following defines are used
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*/
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#ifdef AES_ASM
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#define ENCRYPTION_KEY_SCHEDULE
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#define DECRYPTION_KEY_SCHEDULE
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#else
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/* 4. FUNCTIONS REQUIRED
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This implementation provides five main subroutines which provide for
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setting block length, setting encryption and decryption keys and for
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encryption and decryption. When the assembler code is not being used
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the following definition blocks allow the selection of the routines
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that are to be included in the compilation.
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*/
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#if 1
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#define ENCRYPTION_KEY_SCHEDULE
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#endif
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#if 1
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#define DECRYPTION_KEY_SCHEDULE
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#endif
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#if 1
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#define ENCRYPTION
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#endif
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#if 1
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#define DECRYPTION
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#endif
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#endif
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/* 5. BYTE ORDER WITHIN 32 BIT WORDS
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The fundamental data processing units in Rijndael are 8-bit bytes. The
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input, output and key input are all enumerated arrays of bytes in which
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bytes are numbered starting at zero and increasing to one less than the
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number of bytes in the array in question. This enumeration is only used
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for naming bytes and does not imply any adjacency or order relationship
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from one byte to another. When these inputs and outputs are considered
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as bit sequences, bits 8*n to 8*n+7 of the bit sequence are mapped to
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byte[n] with bit 8n+i in the sequence mapped to bit 7-i within the byte.
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In this implementation bits are numbered from 0 to 7 starting at the
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numerically least significant end of each byte (bit n represents 2^n).
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However, Rijndael can be implemented more efficiently using 32-bit
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words by packing bytes into words so that bytes 4*n to 4*n+3 are placed
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into word[n]. While in principle these bytes can be assembled into words
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in any positions, this implementation only supports the two formats in
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which bytes in adjacent positions within words also have adjacent byte
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numbers. This order is called big-endian if the lowest numbered bytes
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in words have the highest numeric significance and little-endian if the
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opposite applies.
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This code can work in either order irrespective of the order used by the
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machine on which it runs. Normally the internal byte order will be set
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to the order of the processor on which the code is to be run but this
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define can be used to reverse this in special situations
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*/
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#if 1
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#define INTERNAL_BYTE_ORDER PLATFORM_BYTE_ORDER
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#elif defined(AES_LITTLE_ENDIAN)
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#define INTERNAL_BYTE_ORDER AES_LITTLE_ENDIAN
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#elif defined(AES_BIG_ENDIAN)
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#define INTERNAL_BYTE_ORDER AES_BIG_ENDIAN
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#endif
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/* 6. FAST INPUT/OUTPUT OPERATIONS.
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On some machines it is possible to improve speed by transferring the
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bytes in the input and output arrays to and from the internal 32-bit
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variables by addressing these arrays as if they are arrays of 32-bit
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words. On some machines this will always be possible but there may
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be a large performance penalty if the byte arrays are not aligned on
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the normal word boundaries. On other machines this technique will
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lead to memory access errors when such 32-bit word accesses are not
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properly aligned. The option SAFE_IO avoids such problems but will
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often be slower on those machines that support misaligned access
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(especially so if care is taken to align the input and output byte
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arrays on 32-bit word boundaries). If SAFE_IO is not defined it is
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assumed that access to byte arrays as if they are arrays of 32-bit
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words will not cause problems when such accesses are misaligned.
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*/
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#if 1
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#define SAFE_IO
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#endif
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/* 7. LOOP UNROLLING
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The code for encryption and decrytpion cycles through a number of rounds
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that can be implemented either in a loop or by expanding the code into a
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long sequence of instructions, the latter producing a larger program but
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one that will often be much faster. The latter is called loop unrolling.
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There are also potential speed advantages in expanding two iterations in
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a loop with half the number of iterations, which is called partial loop
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unrolling. The following options allow partial or full loop unrolling
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to be set independently for encryption and decryption
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*/
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#if 1
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#define ENC_UNROLL FULL
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#elif 0
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#define ENC_UNROLL PARTIAL
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#else
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#define ENC_UNROLL NONE
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#endif
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#if 1
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#define DEC_UNROLL FULL
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#elif 0
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#define DEC_UNROLL PARTIAL
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#else
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#define DEC_UNROLL NONE
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#endif
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/* 8. FIXED OR DYNAMIC TABLES
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When this section is included the tables used by the code are comipled
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statically into the binary file. Otherwise they are computed once when
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the code is first used.
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*/
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#if 1
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#define FIXED_TABLES
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#endif
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/* 9. FAST FINITE FIELD OPERATIONS
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If this section is included, tables are used to provide faster finite
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field arithmetic (this has no effect if FIXED_TABLES is defined).
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*/
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#if 1
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#define FF_TABLES
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#endif
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/* 10. INTERNAL STATE VARIABLE FORMAT
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The internal state of Rijndael is stored in a number of local 32-bit
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word varaibles which can be defined either as an array or as individual
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names variables. Include this section if you want to store these local
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varaibles in arrays. Otherwise individual local variables will be used.
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*/
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#if 1
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#define ARRAYS
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#endif
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/* In this implementation the columns of the state array are each held in
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32-bit words. The state array can be held in various ways: in an array
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of words, in a number of individual word variables or in a number of
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processor registers. The following define maps a variable name x and
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a column number c to the way the state array variable is to be held.
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The first define below maps the state into an array x[c] whereas the
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second form maps the state into a number of individual variables x0,
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x1, etc. Another form could map individual state colums to machine
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register names.
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*/
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#if defined(ARRAYS)
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#define s(x,c) x[c]
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#else
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#define s(x,c) x##c
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#endif
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/* 11. VARIABLE BLOCK SIZE SPEED
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This section is only relevant if you wish to use the variable block
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length feature of the code. Include this section if you place more
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emphasis on speed rather than code size.
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*/
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#if 1
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#define FAST_VARIABLE
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#endif
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/* 12. INTERNAL TABLE CONFIGURATION
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This cipher proceeds by repeating in a number of cycles known as 'rounds'
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which are implemented by a round function which can optionally be speeded
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up using tables. The basic tables are each 256 32-bit words, with either
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one or four tables being required for each round function depending on
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how much speed is required. The encryption and decryption round functions
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are different and the last encryption and decrytpion round functions are
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different again making four different round functions in all.
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This means that:
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1. Normal encryption and decryption rounds can each use either 0, 1
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or 4 tables and table spaces of 0, 1024 or 4096 bytes each.
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2. The last encryption and decryption rounds can also use either 0, 1
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or 4 tables and table spaces of 0, 1024 or 4096 bytes each.
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Include or exclude the appropriate definitions below to set the number
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of tables used by this implementation.
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*/
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#if 1 /* set tables for the normal encryption round */
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#define ENC_ROUND FOUR_TABLES
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#elif 0
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#define ENC_ROUND ONE_TABLE
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#else
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#define ENC_ROUND NO_TABLES
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#endif
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#if 1 /* set tables for the last encryption round */
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#define LAST_ENC_ROUND FOUR_TABLES
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#elif 0
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#define LAST_ENC_ROUND ONE_TABLE
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#else
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#define LAST_ENC_ROUND NO_TABLES
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#endif
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#if 1 /* set tables for the normal decryption round */
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#define DEC_ROUND FOUR_TABLES
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#elif 0
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#define DEC_ROUND ONE_TABLE
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#else
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#define DEC_ROUND NO_TABLES
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#endif
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#if 1 /* set tables for the last decryption round */
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#define LAST_DEC_ROUND FOUR_TABLES
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#elif 0
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#define LAST_DEC_ROUND ONE_TABLE
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#else
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#define LAST_DEC_ROUND NO_TABLES
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#endif
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/* The decryption key schedule can be speeded up with tables in the same
|
|
way that the round functions can. Include or exclude the following
|
|
defines to set this requirement.
|
|
*/
|
|
#if 1
|
|
#define KEY_SCHED FOUR_TABLES
|
|
#elif 0
|
|
#define KEY_SCHED ONE_TABLE
|
|
#else
|
|
#define KEY_SCHED NO_TABLES
|
|
#endif
|
|
|
|
/* END OF CONFIGURATION OPTIONS */
|
|
|
|
#define NO_TABLES 0 /* DO NOT CHANGE */
|
|
#define ONE_TABLE 1 /* DO NOT CHANGE */
|
|
#define FOUR_TABLES 4 /* DO NOT CHANGE */
|
|
#define NONE 0 /* DO NOT CHANGE */
|
|
#define PARTIAL 1 /* DO NOT CHANGE */
|
|
#define FULL 2 /* DO NOT CHANGE */
|
|
|
|
#if defined(BLOCK_SIZE) && ((BLOCK_SIZE & 3) || BLOCK_SIZE < 16 || BLOCK_SIZE > 32)
|
|
#error An illegal block size has been specified.
|
|
#endif
|
|
|
|
#if !defined(BLOCK_SIZE)
|
|
#define RC_LENGTH 29
|
|
#else
|
|
#define RC_LENGTH 5 * BLOCK_SIZE / 4 - (BLOCK_SIZE == 16 ? 10 : 11)
|
|
#endif
|
|
|
|
/* Disable at least some poor combinations of options */
|
|
|
|
#if ENC_ROUND == NO_TABLES && LAST_ENC_ROUND != NO_TABLES
|
|
#undef LAST_ENC_ROUND
|
|
#define LAST_ENC_ROUND NO_TABLES
|
|
#elif ENC_ROUND == ONE_TABLE && LAST_ENC_ROUND == FOUR_TABLES
|
|
#undef LAST_ENC_ROUND
|
|
#define LAST_ENC_ROUND ONE_TABLE
|
|
#endif
|
|
|
|
#if ENC_ROUND == NO_TABLES && ENC_UNROLL != NONE
|
|
#undef ENC_UNROLL
|
|
#define ENC_UNROLL NONE
|
|
#endif
|
|
|
|
#if DEC_ROUND == NO_TABLES && LAST_DEC_ROUND != NO_TABLES
|
|
#undef LAST_DEC_ROUND
|
|
#define LAST_DEC_ROUND NO_TABLES
|
|
#elif DEC_ROUND == ONE_TABLE && LAST_DEC_ROUND == FOUR_TABLES
|
|
#undef LAST_DEC_ROUND
|
|
#define LAST_DEC_ROUND ONE_TABLE
|
|
#endif
|
|
|
|
#if DEC_ROUND == NO_TABLES && DEC_UNROLL != NONE
|
|
#undef DEC_UNROLL
|
|
#define DEC_UNROLL NONE
|
|
#endif
|
|
|
|
/* upr(x,n): rotates bytes within words by n positions, moving bytes to
|
|
higher index positions with wrap around into low positions
|
|
ups(x,n): moves bytes by n positions to higher index positions in
|
|
words but without wrap around
|
|
bval(x,n): extracts a byte from a word
|
|
|
|
NOTE: The definitions given here are intended only for use with
|
|
unsigned variables and with shift counts that are compile
|
|
time constants
|
|
*/
|
|
|
|
#if (INTERNAL_BYTE_ORDER == AES_LITTLE_ENDIAN)
|
|
#if defined(_MSC_VER)
|
|
#define upr(x,n) _lrotl((aes_32t)(x), 8 * (n))
|
|
#else
|
|
#define upr(x,n) ((aes_32t)(x) << 8 * (n) | (aes_32t)(x) >> 32 - 8 * (n))
|
|
#endif
|
|
#define ups(x,n) ((aes_32t)(x) << 8 * (n))
|
|
#define bval(x,n) ((aes_08t)((x) >> 8 * (n)))
|
|
#define bytes2word(b0, b1, b2, b3) \
|
|
(((aes_32t)(b3) << 24) | ((aes_32t)(b2) << 16) | ((aes_32t)(b1) << 8) | (b0))
|
|
#endif
|
|
|
|
#if (INTERNAL_BYTE_ORDER == AES_BIG_ENDIAN)
|
|
#define upr(x,n) ((aes_32t)(x) >> 8 * (n) | (aes_32t)(x) << 32 - 8 * (n))
|
|
#define ups(x,n) ((aes_32t)(x) >> 8 * (n)))
|
|
#define bval(x,n) ((aes_08t)((x) >> 24 - 8 * (n)))
|
|
#define bytes2word(b0, b1, b2, b3) \
|
|
(((aes_32t)(b0) << 24) | ((aes_32t)(b1) << 16) | ((aes_32t)(b2) << 8) | (b3))
|
|
#endif
|
|
|
|
#if defined(SAFE_IO)
|
|
|
|
#define word_in(x) bytes2word((x)[0], (x)[1], (x)[2], (x)[3])
|
|
#define word_out(x,v) { (x)[0] = bval(v,0); (x)[1] = bval(v,1); \
|
|
(x)[2] = bval(v,2); (x)[3] = bval(v,3); }
|
|
|
|
#elif (INTERNAL_BYTE_ORDER == PLATFORM_BYTE_ORDER)
|
|
|
|
#define word_in(x) *(aes_32t*)(x)
|
|
#define word_out(x,v) *(aes_32t*)(x) = (v)
|
|
|
|
#else
|
|
|
|
#if !defined(bswap_32)
|
|
#if !defined(_MSC_VER)
|
|
#define _lrotl(x,n) ((aes_32t)(x) << n | (aes_32t)(x) >> 32 - n)
|
|
#endif
|
|
#define bswap_32(x) ((_lrotl((x),8) & 0x00ff00ff) | (_lrotl((x),24) & 0xff00ff00))
|
|
#endif
|
|
|
|
#define word_in(x) bswap_32(*(aes_32t*)(x))
|
|
#define word_out(x,v) *(aes_32t*)(x) = bswap_32(v)
|
|
|
|
#endif
|
|
|
|
/* the finite field modular polynomial and elements */
|
|
|
|
#define WPOLY 0x011b
|
|
#define BPOLY 0x1b
|
|
|
|
/* multiply four bytes in GF(2^8) by 'x' {02} in parallel */
|
|
|
|
#define m1 0x80808080
|
|
#define m2 0x7f7f7f7f
|
|
#define FFmulX(x) ((((x) & m2) << 1) ^ ((((x) & m1) >> 7) * BPOLY))
|
|
|
|
/* The following defines provide alternative definitions of FFmulX that might
|
|
give improved performance if a fast 32-bit multiply is not available. Note
|
|
that a temporary variable u needs to be defined where FFmulX is used.
|
|
|
|
#define FFmulX(x) (u = (x) & m1, u |= (u >> 1), ((x) & m2) << 1) ^ ((u >> 3) | (u >> 6))
|
|
#define m4 (0x01010101 * BPOLY)
|
|
#define FFmulX(x) (u = (x) & m1, ((x) & m2) << 1) ^ ((u - (u >> 7)) & m4)
|
|
*/
|
|
|
|
/* Work out which tables are needed for the different options */
|
|
|
|
#ifdef AES_ASM
|
|
#ifdef ENC_ROUND
|
|
#undef ENC_ROUND
|
|
#endif
|
|
#define ENC_ROUND FOUR_TABLES
|
|
#ifdef LAST_ENC_ROUND
|
|
#undef LAST_ENC_ROUND
|
|
#endif
|
|
#define LAST_ENC_ROUND FOUR_TABLES
|
|
#ifdef DEC_ROUND
|
|
#undef DEC_ROUND
|
|
#endif
|
|
#define DEC_ROUND FOUR_TABLES
|
|
#ifdef LAST_DEC_ROUND
|
|
#undef LAST_DEC_ROUND
|
|
#endif
|
|
#define LAST_DEC_ROUND FOUR_TABLES
|
|
#ifdef KEY_SCHED
|
|
#undef KEY_SCHED
|
|
#define KEY_SCHED FOUR_TABLES
|
|
#endif
|
|
#endif
|
|
|
|
#if defined(ENCRYPTION) || defined(AES_ASM)
|
|
#if ENC_ROUND == ONE_TABLE
|
|
#define FT1_SET
|
|
#elif ENC_ROUND == FOUR_TABLES
|
|
#define FT4_SET
|
|
#else
|
|
#define SBX_SET
|
|
#endif
|
|
#if LAST_ENC_ROUND == ONE_TABLE
|
|
#define FL1_SET
|
|
#elif LAST_ENC_ROUND == FOUR_TABLES
|
|
#define FL4_SET
|
|
#elif !defined(SBX_SET)
|
|
#define SBX_SET
|
|
#endif
|
|
#endif
|
|
|
|
#if defined(DECRYPTION) || defined(AES_ASM)
|
|
#if DEC_ROUND == ONE_TABLE
|
|
#define IT1_SET
|
|
#elif DEC_ROUND == FOUR_TABLES
|
|
#define IT4_SET
|
|
#else
|
|
#define ISB_SET
|
|
#endif
|
|
#if LAST_DEC_ROUND == ONE_TABLE
|
|
#define IL1_SET
|
|
#elif LAST_DEC_ROUND == FOUR_TABLES
|
|
#define IL4_SET
|
|
#elif !defined(ISB_SET)
|
|
#define ISB_SET
|
|
#endif
|
|
#endif
|
|
|
|
#if defined(ENCRYPTION_KEY_SCHEDULE) || defined(DECRYPTION_KEY_SCHEDULE)
|
|
#if KEY_SCHED == ONE_TABLE
|
|
#define LS1_SET
|
|
#define IM1_SET
|
|
#elif KEY_SCHED == FOUR_TABLES
|
|
#define LS4_SET
|
|
#define IM4_SET
|
|
#elif !defined(SBX_SET)
|
|
#define SBX_SET
|
|
#endif
|
|
#endif
|
|
|
|
#ifdef FIXED_TABLES
|
|
#define prefx extern const
|
|
#else
|
|
#define prefx extern
|
|
extern aes_08t tab_init;
|
|
void gen_tabs(void);
|
|
#endif
|
|
|
|
prefx aes_32t rcon_tab[29];
|
|
|
|
#ifdef SBX_SET
|
|
prefx aes_08t s_box[256];
|
|
#endif
|
|
|
|
#ifdef ISB_SET
|
|
prefx aes_08t inv_s_box[256];
|
|
#endif
|
|
|
|
#ifdef FT1_SET
|
|
prefx aes_32t ft_tab[256];
|
|
#endif
|
|
|
|
#ifdef FT4_SET
|
|
prefx aes_32t ft_tab[4][256];
|
|
#endif
|
|
|
|
#ifdef FL1_SET
|
|
prefx aes_32t fl_tab[256];
|
|
#endif
|
|
|
|
#ifdef FL4_SET
|
|
prefx aes_32t fl_tab[4][256];
|
|
#endif
|
|
|
|
#ifdef IT1_SET
|
|
prefx aes_32t it_tab[256];
|
|
#endif
|
|
|
|
#ifdef IT4_SET
|
|
prefx aes_32t it_tab[4][256];
|
|
#endif
|
|
|
|
#ifdef IL1_SET
|
|
prefx aes_32t il_tab[256];
|
|
#endif
|
|
|
|
#ifdef IL4_SET
|
|
prefx aes_32t il_tab[4][256];
|
|
#endif
|
|
|
|
#ifdef LS1_SET
|
|
#ifdef FL1_SET
|
|
#undef LS1_SET
|
|
#else
|
|
prefx aes_32t ls_tab[256];
|
|
#endif
|
|
#endif
|
|
|
|
#ifdef LS4_SET
|
|
#ifdef FL4_SET
|
|
#undef LS4_SET
|
|
#else
|
|
prefx aes_32t ls_tab[4][256];
|
|
#endif
|
|
#endif
|
|
|
|
#ifdef IM1_SET
|
|
prefx aes_32t im_tab[256];
|
|
#endif
|
|
|
|
#ifdef IM4_SET
|
|
prefx aes_32t im_tab[4][256];
|
|
#endif
|
|
|
|
/* Set the number of columns in nc. Note that it is important
|
|
that nc is a constant which is known at compile time if the
|
|
highest speed version of the code is needed.
|
|
*/
|
|
|
|
#if defined(BLOCK_SIZE)
|
|
#define nc (BLOCK_SIZE >> 2)
|
|
#else
|
|
#define nc (cx->n_blk >> 2)
|
|
#endif
|
|
|
|
/* generic definitions of Rijndael macros that use tables */
|
|
|
|
#define no_table(x,box,vf,rf,c) bytes2word( \
|
|
box[bval(vf(x,0,c),rf(0,c))], \
|
|
box[bval(vf(x,1,c),rf(1,c))], \
|
|
box[bval(vf(x,2,c),rf(2,c))], \
|
|
box[bval(vf(x,3,c),rf(3,c))])
|
|
|
|
#define one_table(x,op,tab,vf,rf,c) \
|
|
( tab[bval(vf(x,0,c),rf(0,c))] \
|
|
^ op(tab[bval(vf(x,1,c),rf(1,c))],1) \
|
|
^ op(tab[bval(vf(x,2,c),rf(2,c))],2) \
|
|
^ op(tab[bval(vf(x,3,c),rf(3,c))],3))
|
|
|
|
#define four_tables(x,tab,vf,rf,c) \
|
|
( tab[0][bval(vf(x,0,c),rf(0,c))] \
|
|
^ tab[1][bval(vf(x,1,c),rf(1,c))] \
|
|
^ tab[2][bval(vf(x,2,c),rf(2,c))] \
|
|
^ tab[3][bval(vf(x,3,c),rf(3,c))])
|
|
|
|
#define vf1(x,r,c) (x)
|
|
#define rf1(r,c) (r)
|
|
#define rf2(r,c) ((r-c)&3)
|
|
|
|
/* perform forward and inverse column mix operation on four bytes in long word x in */
|
|
/* parallel. NOTE: x must be a simple variable, NOT an expression in these macros. */
|
|
|
|
#define dec_fmvars
|
|
#if defined(FM4_SET) /* not currently used */
|
|
#define fwd_mcol(x) four_tables(x,fm_tab,vf1,rf1,0)
|
|
#elif defined(FM1_SET) /* not currently used */
|
|
#define fwd_mcol(x) one_table(x,upr,fm_tab,vf1,rf1,0)
|
|
#else
|
|
#undef dec_fmvars
|
|
#define dec_fmvars aes_32t f1, f2;
|
|
#define fwd_mcol(x) (f1 = (x), f2 = FFmulX(f1), f2 ^ upr(f1 ^ f2, 3) ^ upr(f1, 2) ^ upr(f1, 1))
|
|
#endif
|
|
|
|
#define dec_imvars
|
|
#if defined(IM4_SET)
|
|
#define inv_mcol(x) four_tables(x,im_tab,vf1,rf1,0)
|
|
#elif defined(IM1_SET)
|
|
#define inv_mcol(x) one_table(x,upr,im_tab,vf1,rf1,0)
|
|
#else
|
|
#undef dec_imvars
|
|
#define dec_imvars aes_32t f2, f4, f8, f9;
|
|
#define inv_mcol(x) \
|
|
(f9 = (x), f2 = FFmulX(f9), f4 = FFmulX(f2), f8 = FFmulX(f4), f9 ^= f8, \
|
|
f2 ^= f4 ^ f8 ^ upr(f2 ^ f9,3) ^ upr(f4 ^ f9,2) ^ upr(f9,1))
|
|
#endif
|
|
|
|
#if defined(FL4_SET)
|
|
#define ls_box(x,c) four_tables(x,fl_tab,vf1,rf2,c)
|
|
#elif defined(LS4_SET)
|
|
#define ls_box(x,c) four_tables(x,ls_tab,vf1,rf2,c)
|
|
#elif defined(FL1_SET)
|
|
#define ls_box(x,c) one_table(x,upr,fl_tab,vf1,rf2,c)
|
|
#elif defined(LS1_SET)
|
|
#define ls_box(x,c) one_table(x,upr,ls_tab,vf1,rf2,c)
|
|
#else
|
|
#define ls_box(x,c) no_table(x,s_box,vf1,rf2,c)
|
|
#endif
|
|
|
|
#endif
|