/* * \brief Generic file encryption program using generic wrappers for configured * security. * * Copyright (C) 2006-2011, ARM Limited, All Rights Reserved * * This file is part of mbed TLS (https://tls.mbed.org) * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #if !defined(POLARSSL_CONFIG_FILE) #include "polarssl/config.h" #else #include POLARSSL_CONFIG_FILE #endif #if defined(POLARSSL_PLATFORM_C) #include "polarssl/platform.h" #else #include #define polarssl_fprintf fprintf #define polarssl_printf printf #endif #if defined(POLARSSL_CIPHER_C) && defined(POLARSSL_MD_C) && \ defined(POLARSSL_FS_IO) #include "polarssl/cipher.h" #include "polarssl/md.h" #include #include #include #endif #if defined(_WIN32) #include #if !defined(_WIN32_WCE) #include #endif #else #include #include #endif #define MODE_ENCRYPT 0 #define MODE_DECRYPT 1 #define USAGE \ "\n crypt_and_hash \n" \ "\n : 0 = encrypt, 1 = decrypt\n" \ "\n example: crypt_and_hash 0 file file.aes AES-128-CBC SHA1 hex:E76B2413958B00E193\n" \ "\n" #if !defined(POLARSSL_CIPHER_C) || !defined(POLARSSL_MD_C) || \ !defined(POLARSSL_FS_IO) int main( void ) { polarssl_printf("POLARSSL_CIPHER_C and/or POLARSSL_MD_C and/or POLARSSL_FS_IO not defined.\n"); return( 0 ); } #else int main( int argc, char *argv[] ) { int ret = 1, i, n; int mode, lastn; size_t keylen, ilen, olen; FILE *fkey, *fin = NULL, *fout = NULL; char *p; unsigned char IV[16]; unsigned char key[512]; unsigned char digest[POLARSSL_MD_MAX_SIZE]; unsigned char buffer[1024]; unsigned char output[1024]; unsigned char diff; const cipher_info_t *cipher_info; const md_info_t *md_info; cipher_context_t cipher_ctx; md_context_t md_ctx; #if defined(_WIN32_WCE) long filesize, offset; #elif defined(_WIN32) LARGE_INTEGER li_size; __int64 filesize, offset; #else off_t filesize, offset; #endif cipher_init( &cipher_ctx ); md_init( &md_ctx ); /* * Parse the command-line arguments. */ if( argc != 7 ) { const int *list; polarssl_printf( USAGE ); polarssl_printf( "Available ciphers:\n" ); list = cipher_list(); while( *list ) { cipher_info = cipher_info_from_type( *list ); polarssl_printf( " %s\n", cipher_info->name ); list++; } polarssl_printf( "\nAvailable message digests:\n" ); list = md_list(); while( *list ) { md_info = md_info_from_type( *list ); polarssl_printf( " %s\n", md_info->name ); list++; } #if defined(_WIN32) polarssl_printf( "\n Press Enter to exit this program.\n" ); fflush( stdout ); getchar(); #endif goto exit; } mode = atoi( argv[1] ); if( mode != MODE_ENCRYPT && mode != MODE_DECRYPT ) { polarssl_fprintf( stderr, "invalid operation mode\n" ); goto exit; } if( strcmp( argv[2], argv[3] ) == 0 ) { polarssl_fprintf( stderr, "input and output filenames must differ\n" ); goto exit; } if( ( fin = fopen( argv[2], "rb" ) ) == NULL ) { polarssl_fprintf( stderr, "fopen(%s,rb) failed\n", argv[2] ); goto exit; } if( ( fout = fopen( argv[3], "wb+" ) ) == NULL ) { polarssl_fprintf( stderr, "fopen(%s,wb+) failed\n", argv[3] ); goto exit; } /* * Read the Cipher and MD from the command line */ cipher_info = cipher_info_from_string( argv[4] ); if( cipher_info == NULL ) { polarssl_fprintf( stderr, "Cipher '%s' not found\n", argv[4] ); goto exit; } if( ( ret = cipher_init_ctx( &cipher_ctx, cipher_info) ) != 0 ) { polarssl_fprintf( stderr, "cipher_init_ctx failed\n" ); goto exit; } md_info = md_info_from_string( argv[5] ); if( md_info == NULL ) { polarssl_fprintf( stderr, "Message Digest '%s' not found\n", argv[5] ); goto exit; } md_init_ctx( &md_ctx, md_info); /* * Read the secret key and clean the command line. */ if( ( fkey = fopen( argv[6], "rb" ) ) != NULL ) { keylen = fread( key, 1, sizeof( key ), fkey ); fclose( fkey ); } else { if( memcmp( argv[6], "hex:", 4 ) == 0 ) { p = &argv[6][4]; keylen = 0; while( sscanf( p, "%02X", &n ) > 0 && keylen < (int) sizeof( key ) ) { key[keylen++] = (unsigned char) n; p += 2; } } else { keylen = strlen( argv[6] ); if( keylen > (int) sizeof( key ) ) keylen = (int) sizeof( key ); memcpy( key, argv[6], keylen ); } } memset( argv[6], 0, strlen( argv[6] ) ); #if defined(_WIN32_WCE) filesize = fseek( fin, 0L, SEEK_END ); #else #if defined(_WIN32) /* * Support large files (> 2Gb) on Win32 */ li_size.QuadPart = 0; li_size.LowPart = SetFilePointer( (HANDLE) _get_osfhandle( _fileno( fin ) ), li_size.LowPart, &li_size.HighPart, FILE_END ); if( li_size.LowPart == 0xFFFFFFFF && GetLastError() != NO_ERROR ) { polarssl_fprintf( stderr, "SetFilePointer(0,FILE_END) failed\n" ); goto exit; } filesize = li_size.QuadPart; #else if( ( filesize = lseek( fileno( fin ), 0, SEEK_END ) ) < 0 ) { perror( "lseek" ); goto exit; } #endif #endif if( fseek( fin, 0, SEEK_SET ) < 0 ) { polarssl_fprintf( stderr, "fseek(0,SEEK_SET) failed\n" ); goto exit; } if( mode == MODE_ENCRYPT ) { /* * Generate the initialization vector as: * IV = SHA-256( filesize || filename )[0..15] */ for( i = 0; i < 8; i++ ) buffer[i] = (unsigned char)( filesize >> ( i << 3 ) ); p = argv[2]; md_starts( &md_ctx ); md_update( &md_ctx, buffer, 8 ); md_update( &md_ctx, (unsigned char *) p, strlen( p ) ); md_finish( &md_ctx, digest ); memcpy( IV, digest, 16 ); /* * The last four bits in the IV are actually used * to store the file size modulo the AES block size. */ lastn = (int)( filesize & 0x0F ); IV[15] = (unsigned char) ( ( IV[15] & 0xF0 ) | lastn ); /* * Append the IV at the beginning of the output. */ if( fwrite( IV, 1, 16, fout ) != 16 ) { polarssl_fprintf( stderr, "fwrite(%d bytes) failed\n", 16 ); goto exit; } /* * Hash the IV and the secret key together 8192 times * using the result to setup the AES context and HMAC. */ memset( digest, 0, 32 ); memcpy( digest, IV, 16 ); for( i = 0; i < 8192; i++ ) { md_starts( &md_ctx ); md_update( &md_ctx, digest, 32 ); md_update( &md_ctx, key, keylen ); md_finish( &md_ctx, digest ); } memset( key, 0, sizeof( key ) ); if( cipher_setkey( &cipher_ctx, digest, cipher_info->key_length, POLARSSL_ENCRYPT ) != 0 ) { polarssl_fprintf( stderr, "cipher_setkey() returned error\n"); goto exit; } if( cipher_set_iv( &cipher_ctx, IV, 16 ) != 0 ) { polarssl_fprintf( stderr, "cipher_set_iv() returned error\n"); goto exit; } if( cipher_reset( &cipher_ctx ) != 0 ) { polarssl_fprintf( stderr, "cipher_reset() returned error\n"); goto exit; } md_hmac_starts( &md_ctx, digest, 32 ); /* * Encrypt and write the ciphertext. */ for( offset = 0; offset < filesize; offset += cipher_get_block_size( &cipher_ctx ) ) { ilen = ( (unsigned int) filesize - offset > cipher_get_block_size( &cipher_ctx ) ) ? cipher_get_block_size( &cipher_ctx ) : (unsigned int) ( filesize - offset ); if( fread( buffer, 1, ilen, fin ) != ilen ) { polarssl_fprintf( stderr, "fread(%ld bytes) failed\n", (long) ilen ); goto exit; } if( cipher_update( &cipher_ctx, buffer, ilen, output, &olen ) != 0 ) { polarssl_fprintf( stderr, "cipher_update() returned error\n"); goto exit; } md_hmac_update( &md_ctx, output, olen ); if( fwrite( output, 1, olen, fout ) != olen ) { polarssl_fprintf( stderr, "fwrite(%ld bytes) failed\n", (long) olen ); goto exit; } } if( cipher_finish( &cipher_ctx, output, &olen ) != 0 ) { polarssl_fprintf( stderr, "cipher_finish() returned error\n" ); goto exit; } md_hmac_update( &md_ctx, output, olen ); if( fwrite( output, 1, olen, fout ) != olen ) { polarssl_fprintf( stderr, "fwrite(%ld bytes) failed\n", (long) olen ); goto exit; } /* * Finally write the HMAC. */ md_hmac_finish( &md_ctx, digest ); if( fwrite( digest, 1, md_get_size( md_info ), fout ) != md_get_size( md_info ) ) { polarssl_fprintf( stderr, "fwrite(%d bytes) failed\n", md_get_size( md_info ) ); goto exit; } } if( mode == MODE_DECRYPT ) { /* * The encrypted file must be structured as follows: * * 00 .. 15 Initialization Vector * 16 .. 31 AES Encrypted Block #1 * .. * N*16 .. (N+1)*16 - 1 AES Encrypted Block #N * (N+1)*16 .. (N+1)*16 + 32 HMAC-SHA-256(ciphertext) */ if( filesize < 16 + md_get_size( md_info ) ) { polarssl_fprintf( stderr, "File too short to be encrypted.\n" ); goto exit; } if( ( ( filesize - md_get_size( md_info ) ) % cipher_get_block_size( &cipher_ctx ) ) != 0 ) { polarssl_fprintf( stderr, "File content not a multiple of the block size (%d).\n", cipher_get_block_size( &cipher_ctx )); goto exit; } /* * Subtract the IV + HMAC length. */ filesize -= ( 16 + md_get_size( md_info ) ); /* * Read the IV and original filesize modulo 16. */ if( fread( buffer, 1, 16, fin ) != 16 ) { polarssl_fprintf( stderr, "fread(%d bytes) failed\n", 16 ); goto exit; } memcpy( IV, buffer, 16 ); lastn = IV[15] & 0x0F; /* * Hash the IV and the secret key together 8192 times * using the result to setup the AES context and HMAC. */ memset( digest, 0, 32 ); memcpy( digest, IV, 16 ); for( i = 0; i < 8192; i++ ) { md_starts( &md_ctx ); md_update( &md_ctx, digest, 32 ); md_update( &md_ctx, key, keylen ); md_finish( &md_ctx, digest ); } memset( key, 0, sizeof( key ) ); if( cipher_setkey( &cipher_ctx, digest, cipher_info->key_length, POLARSSL_DECRYPT ) != 0 ) { polarssl_fprintf( stderr, "cipher_setkey() returned error\n" ); goto exit; } if( cipher_set_iv( &cipher_ctx, IV, 16 ) != 0 ) { polarssl_fprintf( stderr, "cipher_set_iv() returned error\n" ); goto exit; } if( cipher_reset( &cipher_ctx ) != 0 ) { polarssl_fprintf( stderr, "cipher_reset() returned error\n" ); goto exit; } md_hmac_starts( &md_ctx, digest, 32 ); /* * Decrypt and write the plaintext. */ for( offset = 0; offset < filesize; offset += cipher_get_block_size( &cipher_ctx ) ) { if( fread( buffer, 1, cipher_get_block_size( &cipher_ctx ), fin ) != (size_t) cipher_get_block_size( &cipher_ctx ) ) { polarssl_fprintf( stderr, "fread(%d bytes) failed\n", cipher_get_block_size( &cipher_ctx ) ); goto exit; } md_hmac_update( &md_ctx, buffer, cipher_get_block_size( &cipher_ctx ) ); if( cipher_update( &cipher_ctx, buffer, cipher_get_block_size( &cipher_ctx ), output, &olen ) != 0 ) { polarssl_fprintf( stderr, "cipher_update() returned error\n" ); goto exit; } if( fwrite( output, 1, olen, fout ) != olen ) { polarssl_fprintf( stderr, "fwrite(%ld bytes) failed\n", (long) olen ); goto exit; } } /* * Verify the message authentication code. */ md_hmac_finish( &md_ctx, digest ); if( fread( buffer, 1, md_get_size( md_info ), fin ) != md_get_size( md_info ) ) { polarssl_fprintf( stderr, "fread(%d bytes) failed\n", md_get_size( md_info ) ); goto exit; } /* Use constant-time buffer comparison */ diff = 0; for( i = 0; i < md_get_size( md_info ); i++ ) diff |= digest[i] ^ buffer[i]; if( diff != 0 ) { polarssl_fprintf( stderr, "HMAC check failed: wrong key, " "or file corrupted.\n" ); goto exit; } /* * Write the final block of data */ cipher_finish( &cipher_ctx, output, &olen ); if( fwrite( output, 1, olen, fout ) != olen ) { polarssl_fprintf( stderr, "fwrite(%ld bytes) failed\n", (long) olen ); goto exit; } } ret = 0; exit: if( fin ) fclose( fin ); if( fout ) fclose( fout ); memset( buffer, 0, sizeof( buffer ) ); memset( digest, 0, sizeof( digest ) ); cipher_free( &cipher_ctx ); md_free( &md_ctx ); return( ret ); } #endif /* POLARSSL_CIPHER_C && POLARSSL_MD_C && POLARSSL_FS_IO */