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view aes.c @ 10:439b7aaaec9e
Get aes from avr231 appnote instead
author | Matt Johnston <matt@ucc.asn.au> |
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date | Wed, 12 Jun 2013 22:57:44 +0800 |
parents | 87c8d0a11906 |
children |
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#include "aes.h" //#include "loader.h" // #define KEY_COUNT 1 #if KEY_COUNT > 0 //#include "aeskeys.inc" typedef unsigned char byte; #define BPOLY 0x1b //!< Lower 8 bits of (x^8+x^4+x^3+x+1), ie. (x^4+x^3+x+1). #define BLOCKSIZE 16 //!< Block size in number of bytes. #if KEY_COUNT == 1 #define KEYBITS 128 //!< Use AES128. #elif KEY_COUNT == 2 #define KEYBITS 192 //!< Use AES196. #elif KEY_COUNT == 3 #define KEYBITS 256 //!< Use AES256. #else #error Use 1, 2 or 3 keys! #endif #if KEYBITS == 128 #define ROUNDS 10 //!< Number of rounds. #define KEYLENGTH 16 //!< Key length in number of bytes. #elif KEYBITS == 192 #define ROUNDS 12 //!< Number of rounds. #define KEYLENGTH 24 //!< // Key length in number of bytes. #elif KEYBITS == 256 #define ROUNDS 14 //!< Number of rounds. #define KEYLENGTH 32 //!< Key length in number of bytes. #else #error Key must be 128, 192 or 256 bits! #endif #define EXPANDED_KEY_SIZE (BLOCKSIZE * (ROUNDS+1)) //!< 176, 208 or 240 bytes. byte block1[ 256 ]; //!< Workspace 1. byte block2[ 256 ]; //!< Worksapce 2. byte * powTbl; //!< Final location of exponentiation lookup table. byte * logTbl; //!< Final location of logarithm lookup table. byte * sBox; //!< Final location of s-box. byte * sBoxInv; //!< Final location of inverse s-box. byte * expandedKey; //!< Final location of expanded key. void CalcPowLog( byte * powTbl, byte * logTbl ) { byte i = 0; byte t = 1; do { // Use 0x03 as root for exponentiation and logarithms. powTbl[i] = t; logTbl[t] = i; i++; // Muliply t by 3 in GF(2^8). t ^= (t << 1) ^ (t & 0x80 ? BPOLY : 0); } while( t != 1 ); // Cyclic properties ensure that i < 255. powTbl[255] = powTbl[0]; // 255 = '-0', 254 = -1, etc. } void CalcSBox( byte * sBox ) { byte i, rot; byte temp; byte result; // Fill all entries of sBox[]. i = 0; do { // Inverse in GF(2^8). if( i > 0 ) { temp = powTbl[ 255 - logTbl[i] ]; } else { temp = 0; } // Affine transformation in GF(2). result = temp ^ 0x63; // Start with adding a vector in GF(2). for( rot = 0; rot < 4; rot++ ) { // Rotate left. temp = (temp<<1) | (temp>>7); // Add rotated byte in GF(2). result ^= temp; } // Put result in table. sBox[i] = result; } while( ++i != 0 ); } void CalcSBoxInv( byte * sBox, byte * sBoxInv ) { byte i = 0; byte j = 0; // Iterate through all elements in sBoxInv using i. do { // Search through sBox using j. do { // Check if current j is the inverse of current i. if( sBox[ j ] == i ) { // If so, set sBoxInc and indicate search finished. sBoxInv[ i ] = j; j = 255; } } while( ++j != 0 ); } while( ++i != 0 ); } void CycleLeft( byte * row ) { // Cycle 4 bytes in an array left once. byte temp = row[0]; row[0] = row[1]; row[1] = row[2]; row[2] = row[3]; row[3] = temp; } void InvMixColumn( byte * column ) { byte result0, result1, result2, result3; byte column0, column1, column2, column3; byte xor; // This generates more effective code, at least // with the IAR C compiler. column0 = column[0]; column1 = column[1]; column2 = column[2]; column3 = column[3]; // Partial sums (modular addition using XOR). result0 = column1 ^ column2 ^ column3; result1 = column0 ^ column2 ^ column3; result2 = column0 ^ column1 ^ column3; result3 = column0 ^ column1 ^ column2; // Multiply column bytes by 2 modulo BPOLY. // This operation is done the following way to ensure cycle count // independent from data contents. Take care when changing this code. xor = 0; if (column0 & 0x80) { xor = BPOLY; } column0 <<= 1; column0 ^= xor; xor = 0; if (column1 & 0x80) { xor = BPOLY; } column1 <<= 1; column1 ^= xor; xor = 0; if (column2 & 0x80) { xor = BPOLY; } column2 <<= 1; column2 ^= xor; xor = 0; if (column3 & 0x80) { xor = BPOLY; } column3 <<= 1; column3 ^= xor; // More partial sums. result0 ^= column0 ^ column1; result1 ^= column1 ^ column2; result2 ^= column2 ^ column3; result3 ^= column0 ^ column3; // Multiply column bytes by 2 modulo BPOLY. // This operation is done the following way to ensure cycle count // independent from data contents. Take care when changing this code. xor = 0; if (column0 & 0x80) { xor = BPOLY; } column0 <<= 1; column0 ^= xor; xor = 0; if (column1 & 0x80) { xor = BPOLY; } column1 <<= 1; column1 ^= xor; xor = 0; if (column2 & 0x80) { xor = BPOLY; } column2 <<= 1; column2 ^= xor; xor = 0; if (column3 & 0x80) { xor = BPOLY; } column3 <<= 1; column3 ^= xor; // More partial sums. result0 ^= column0 ^ column2; result1 ^= column1 ^ column3; result2 ^= column0 ^ column2; result3 ^= column1 ^ column3; // Multiply column bytes by 2 modulo BPOLY. // This operation is done the following way to ensure cycle count // independent from data contents. Take care when changing this code. xor = 0; if (column0 & 0x80) { xor = BPOLY; } column0 <<= 1; column0 ^= xor; xor = 0; if (column1 & 0x80) { xor = BPOLY; } column1 <<= 1; column1 ^= xor; xor = 0; if (column2 & 0x80) { xor = BPOLY; } column2 <<= 1; column2 ^= xor; xor = 0; if (column3 & 0x80) { xor = BPOLY; } column3 <<= 1; column3 ^= xor; // Final partial sum. column0 ^= column1 ^ column2 ^ column3; // Final sums stored into original column bytes. column[0] = result0 ^ column0; column[1] = result1 ^ column0; column[2] = result2 ^ column0; column[3] = result3 ^ column0; } void SubBytes( byte * bytes, byte count ) { do { *bytes = sBox[ *bytes ]; // Substitute every byte in state. bytes++; } while( --count ); } void InvSubBytesAndXOR( byte * bytes, byte * key, byte count ) { do { // *bytes = sBoxInv[ *bytes ] ^ *key; // Inverse substitute every byte in state and add key. *bytes = block2[ *bytes ] ^ *key; // Use block2 directly. Increases speed. bytes++; key++; } while( --count ); } void InvShiftRows( byte * state ) { byte temp; // Note: State is arranged column by column. // Cycle second row right one time. temp = state[ 1 + 3*4 ]; state[ 1 + 3*4 ] = state[ 1 + 2*4 ]; state[ 1 + 2*4 ] = state[ 1 + 1*4 ]; state[ 1 + 1*4 ] = state[ 1 + 0*4 ]; state[ 1 + 0*4 ] = temp; // Cycle third row right two times. temp = state[ 2 + 0*4 ]; state[ 2 + 0*4 ] = state[ 2 + 2*4 ]; state[ 2 + 2*4 ] = temp; temp = state[ 2 + 1*4 ]; state[ 2 + 1*4 ] = state[ 2 + 3*4 ]; state[ 2 + 3*4 ] = temp; // Cycle fourth row right three times, ie. left once. temp = state[ 3 + 0*4 ]; state[ 3 + 0*4 ] = state[ 3 + 1*4 ]; state[ 3 + 1*4 ] = state[ 3 + 2*4 ]; state[ 3 + 2*4 ] = state[ 3 + 3*4 ]; state[ 3 + 3*4 ] = temp; } void InvMixColumns( byte * state ) { InvMixColumn( state + 0*4 ); InvMixColumn( state + 1*4 ); InvMixColumn( state + 2*4 ); InvMixColumn( state + 3*4 ); } void XORBytes( byte * bytes1, byte * bytes2, byte count ) { do { *bytes1 ^= *bytes2; // Add in GF(2), ie. XOR. bytes1++; bytes2++; } while( --count ); } void CopyBytes( byte * to, byte * from, byte count ) { do { *to = *from; to++; from++; } while( --count ); } void KeyExpansion( byte * key, byte * expandedKey ) { byte temp[4]; byte i; byte Rcon[4] = { 0x01, 0x00, 0x00, 0x00 }; // Round constant. #if 0 // matt unsigned char BOOTFLASH * key = kTable; #endif // Copy key to start of expanded key. i = KEYLENGTH; do { *expandedKey = *key; expandedKey++; key++; } while( --i ); // Prepare last 4 bytes of key in temp. expandedKey -= 4; temp[0] = *(expandedKey++); temp[1] = *(expandedKey++); temp[2] = *(expandedKey++); temp[3] = *(expandedKey++); // Expand key. i = KEYLENGTH; while( i < BLOCKSIZE*(ROUNDS+1) ) { // Are we at the start of a multiple of the key size? if( (i % KEYLENGTH) == 0 ) { CycleLeft( temp ); // Cycle left once. SubBytes( temp, 4 ); // Substitute each byte. XORBytes( temp, Rcon, 4 ); // Add constant in GF(2). *Rcon = (*Rcon << 1) ^ (*Rcon & 0x80 ? BPOLY : 0); } // Keysize larger than 24 bytes, ie. larger that 192 bits? #if KEYLENGTH > 24 // Are we right past a block size? else if( (i % KEYLENGTH) == BLOCKSIZE ) { SubBytes( temp, 4 ); // Substitute each byte. } #endif // Add bytes in GF(2) one KEYLENGTH away. XORBytes( temp, expandedKey - KEYLENGTH, 4 ); // Copy result to current 4 bytes. *(expandedKey++) = temp[ 0 ]; *(expandedKey++) = temp[ 1 ]; *(expandedKey++) = temp[ 2 ]; *(expandedKey++) = temp[ 3 ]; i += 4; // Next 4 bytes. } } void InvCipher( byte * block, byte * expandedKey ) { byte round = ROUNDS-1; expandedKey += BLOCKSIZE * ROUNDS; XORBytes( block, expandedKey, 16 ); expandedKey -= BLOCKSIZE; do { InvShiftRows( block ); InvSubBytesAndXOR( block, expandedKey, 16 ); expandedKey -= BLOCKSIZE; InvMixColumns( block ); } while( --round ); InvShiftRows( block ); InvSubBytesAndXOR( block, expandedKey, 16 ); } void aesInit( unsigned char *key, unsigned char * tempbuf ) { powTbl = block1; logTbl = block2; CalcPowLog( powTbl, logTbl ); sBox = tempbuf; CalcSBox( sBox ); expandedKey = block1; KeyExpansion( key, expandedKey ); sBoxInv = block2; // Must be block2. CalcSBoxInv( sBox, sBoxInv ); } void aesDecrypt( unsigned char * buffer, unsigned char * chainBlock ) { byte temp[ BLOCKSIZE ]; CopyBytes( temp, buffer, BLOCKSIZE ); InvCipher( buffer, expandedKey ); if (chainBlock) { XORBytes( buffer, chainBlock, BLOCKSIZE ); CopyBytes( chainBlock, temp, BLOCKSIZE ); } } #endif