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rijndael.c
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rijndael.c
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/* Rijndael Block Cipher - rijndael.c
Written by Mike Scott 21st April 1999
Permission for free direct or derivative use is granted subject
to compliance with any conditions that the originators of the
algorithm place on its exploitation.
*/
#include "string.h"
#define u8 unsigned char /* 8 bits */
#define u32 unsigned long /* 32 bits */
#define u64 unsigned long long
/* rotates x one bit to the left */
#define ROTL(x) (((x)>>7)|((x)<<1))
/* Rotates 32-bit word left by 1, 2 or 3 byte */
#define ROTL8(x) (((x)<<8)|((x)>>24))
#define ROTL16(x) (((x)<<16)|((x)>>16))
#define ROTL24(x) (((x)<<24)|((x)>>8))
/* Fixed Data */
static u8 InCo[4]={0xB,0xD,0x9,0xE}; /* Inverse Coefficients */
static u8 fbsub[256];
static u8 rbsub[256];
static u8 ptab[256],ltab[256];
static u32 ftable[256];
static u32 rtable[256];
static u32 rco[30];
/* Parameter-dependent data */
int Nk,Nb,Nr;
u8 fi[24],ri[24];
u32 fkey[120];
u32 rkey[120];
static u32 pack(u8 *b)
{ /* pack bytes into a 32-bit Word */
return ((u32)b[3]<<24)|((u32)b[2]<<16)|((u32)b[1]<<8)|(u32)b[0];
}
static void unpack(u32 a,u8 *b)
{ /* unpack bytes from a word */
b[0]=(u8)a;
b[1]=(u8)(a>>8);
b[2]=(u8)(a>>16);
b[3]=(u8)(a>>24);
}
static u8 xtime(u8 a)
{
u8 b;
if (a&0x80) b=0x1B;
else b=0;
a<<=1;
a^=b;
return a;
}
static u8 bmul(u8 x,u8 y)
{ /* x.y= AntiLog(Log(x) + Log(y)) */
if (x && y) return ptab[(ltab[x]+ltab[y])%255];
else return 0;
}
static u32 SubByte(u32 a)
{
u8 b[4];
unpack(a,b);
b[0]=fbsub[b[0]];
b[1]=fbsub[b[1]];
b[2]=fbsub[b[2]];
b[3]=fbsub[b[3]];
return pack(b);
}
static u8 product(u32 x,u32 y)
{ /* dot product of two 4-byte arrays */
u8 xb[4],yb[4];
unpack(x,xb);
unpack(y,yb);
return bmul(xb[0],yb[0])^bmul(xb[1],yb[1])^bmul(xb[2],yb[2])^bmul(xb[3],yb[3]);
}
static u32 InvMixCol(u32 x)
{ /* matrix Multiplication */
u32 y,m;
u8 b[4];
m=pack(InCo);
b[3]=product(m,x);
m=ROTL24(m);
b[2]=product(m,x);
m=ROTL24(m);
b[1]=product(m,x);
m=ROTL24(m);
b[0]=product(m,x);
y=pack(b);
return y;
}
u8 ByteSub(u8 x)
{
u8 y=ptab[255-ltab[x]]; /* multiplicative inverse */
x=y; x=ROTL(x);
y^=x; x=ROTL(x);
y^=x; x=ROTL(x);
y^=x; x=ROTL(x);
y^=x; y^=0x63;
return y;
}
void gentables(void)
{ /* generate tables */
int i;
u8 y,b[4];
/* use 3 as primitive root to generate power and log tables */
ltab[0]=0;
ptab[0]=1; ltab[1]=0;
ptab[1]=3; ltab[3]=1;
for (i=2;i<256;i++)
{
ptab[i]=ptab[i-1]^xtime(ptab[i-1]);
ltab[ptab[i]]=i;
}
/* affine transformation:- each bit is xored with itself shifted one bit */
fbsub[0]=0x63;
rbsub[0x63]=0;
for (i=1;i<256;i++)
{
y=ByteSub((u8)i);
fbsub[i]=y; rbsub[y]=i;
}
for (i=0,y=1;i<30;i++)
{
rco[i]=y;
y=xtime(y);
}
/* calculate forward and reverse tables */
for (i=0;i<256;i++)
{
y=fbsub[i];
b[3]=y^xtime(y); b[2]=y;
b[1]=y; b[0]=xtime(y);
ftable[i]=pack(b);
y=rbsub[i];
b[3]=bmul(InCo[0],y); b[2]=bmul(InCo[1],y);
b[1]=bmul(InCo[2],y); b[0]=bmul(InCo[3],y);
rtable[i]=pack(b);
}
}
void gkey(int nb,int nk,char *key)
{ /* blocksize=32*nb bits. Key=32*nk bits */
/* currently nb,bk = 4, 6 or 8 */
/* key comes as 4*Nk bytes */
/* Key Scheduler. Create expanded encryption key */
int i,j,k,m,N;
int C1,C2,C3;
u32 CipherKey[8];
Nb=nb; Nk=nk;
/* Nr is number of rounds */
if (Nb>=Nk) Nr=6+Nb;
else Nr=6+Nk;
C1=1;
if (Nb<8) { C2=2; C3=3; }
else { C2=3; C3=4; }
/* pre-calculate forward and reverse increments */
for (m=j=0;j<nb;j++,m+=3)
{
fi[m]=(j+C1)%nb;
fi[m+1]=(j+C2)%nb;
fi[m+2]=(j+C3)%nb;
ri[m]=(nb+j-C1)%nb;
ri[m+1]=(nb+j-C2)%nb;
ri[m+2]=(nb+j-C3)%nb;
}
N=Nb*(Nr+1);
for (i=j=0;i<Nk;i++,j+=4)
{
CipherKey[i]=pack((u8 *)&key[j]);
}
for (i=0;i<Nk;i++) fkey[i]=CipherKey[i];
for (j=Nk,k=0;j<N;j+=Nk,k++)
{
fkey[j]=fkey[j-Nk]^SubByte(ROTL24(fkey[j-1]))^rco[k];
if (Nk<=6)
{
for (i=1;i<Nk && (i+j)<N;i++)
fkey[i+j]=fkey[i+j-Nk]^fkey[i+j-1];
}
else
{
for (i=1;i<4 &&(i+j)<N;i++)
fkey[i+j]=fkey[i+j-Nk]^fkey[i+j-1];
if ((j+4)<N) fkey[j+4]=fkey[j+4-Nk]^SubByte(fkey[j+3]);
for (i=5;i<Nk && (i+j)<N;i++)
fkey[i+j]=fkey[i+j-Nk]^fkey[i+j-1];
}
}
/* now for the expanded decrypt key in reverse order */
for (j=0;j<Nb;j++) rkey[j+N-Nb]=fkey[j];
for (i=Nb;i<N-Nb;i+=Nb)
{
k=N-Nb-i;
for (j=0;j<Nb;j++) rkey[k+j]=InvMixCol(fkey[i+j]);
}
for (j=N-Nb;j<N;j++) rkey[j-N+Nb]=fkey[j];
}
/* There is an obvious time/space trade-off possible here. *
* Instead of just one ftable[], I could have 4, the other *
* 3 pre-rotated to save the ROTL8, ROTL16 and ROTL24 overhead */
void encrypt(char *buff)
{
int i,j,k,m;
u32 a[8],b[8],*x,*y,*t;
for (i=j=0;i<Nb;i++,j+=4)
{
a[i]=pack((u8 *)&buff[j]);
a[i]^=fkey[i];
}
k=Nb;
x=a; y=b;
/* State alternates between a and b */
for (i=1;i<Nr;i++)
{ /* Nr is number of rounds. May be odd. */
/* if Nb is fixed - unroll this next
loop and hard-code in the values of fi[] */
for (m=j=0;j<Nb;j++,m+=3)
{ /* deal with each 32-bit element of the State */
/* This is the time-critical bit */
y[j]=fkey[k++]^ftable[(u8)x[j]]^
ROTL8(ftable[(u8)(x[fi[m]]>>8)])^
ROTL16(ftable[(u8)(x[fi[m+1]]>>16)])^
ROTL24(ftable[x[fi[m+2]]>>24]);
}
t=x; x=y; y=t; /* swap pointers */
}
/* Last Round - unroll if possible */
for (m=j=0;j<Nb;j++,m+=3)
{
y[j]=fkey[k++]^(u32)fbsub[(u8)x[j]]^
ROTL8((u32)fbsub[(u8)(x[fi[m]]>>8)])^
ROTL16((u32)fbsub[(u8)(x[fi[m+1]]>>16)])^
ROTL24((u32)fbsub[x[fi[m+2]]>>24]);
}
for (i=j=0;i<Nb;i++,j+=4)
{
unpack(y[i],(u8 *)&buff[j]);
x[i]=y[i]=0; /* clean up stack */
}
return;
}
void decrypt(char *buff)
{
int i,j,k,m;
u32 a[8],b[8],*x,*y,*t;
for (i=j=0;i<Nb;i++,j+=4)
{
a[i]=pack((u8 *)&buff[j]);
a[i]^=rkey[i];
}
k=Nb;
x=a; y=b;
/* State alternates between a and b */
for (i=1;i<Nr;i++)
{ /* Nr is number of rounds. May be odd. */
/* if Nb is fixed - unroll this next
loop and hard-code in the values of ri[] */
for (m=j=0;j<Nb;j++,m+=3)
{ /* This is the time-critical bit */
y[j]=rkey[k++]^rtable[(u8)x[j]]^
ROTL8(rtable[(u8)(x[ri[m]]>>8)])^
ROTL16(rtable[(u8)(x[ri[m+1]]>>16)])^
ROTL24(rtable[x[ri[m+2]]>>24]);
}
t=x; x=y; y=t; /* swap pointers */
}
/* Last Round - unroll if possible */
for (m=j=0;j<Nb;j++,m+=3)
{
y[j]=rkey[k++]^(u32)rbsub[(u8)x[j]]^
ROTL8((u32)rbsub[(u8)(x[ri[m]]>>8)])^
ROTL16((u32)rbsub[(u8)(x[ri[m+1]]>>16)])^
ROTL24((u32)rbsub[x[ri[m+2]]>>24]);
}
for (i=j=0;i<Nb;i++,j+=4)
{
unpack(y[i],(u8 *)&buff[j]);
x[i]=y[i]=0; /* clean up stack */
}
return;
}
void my_aes_set_key(u8 *key) {
gentables();
gkey(4, 4, (char *)key);
}
// CBC mode decryption
void my_aes_decrypt(u8 *iv, u8 *inbuf, u8 *outbuf, unsigned long long len) {
u8 block[16];
unsigned int blockno = 0, i;
// debug_printf("aes_decrypt(%p, %p, %p, %lld)\n", iv, inbuf, outbuf, len);
for (blockno = 0; blockno <= (len / sizeof(block)); blockno++) {
unsigned int fraction;
if (blockno == (len / sizeof(block))) { // last block
fraction = len % sizeof(block);
if (fraction == 0) break;
memset(block, 0, sizeof(block));
} else fraction = 16;
// debug_printf("block %d: fraction = %d\n", blockno, fraction);
memcpy(block, inbuf + blockno * sizeof(block), fraction);
decrypt((char *)block);
u8 *ctext_ptr;
if (blockno == 0) ctext_ptr = iv;
else ctext_ptr = inbuf + (blockno-1) * sizeof(block);
for(i=0; i < fraction; i++)
outbuf[blockno * sizeof(block) + i] =
ctext_ptr[i] ^ block[i];
// debug_printf("Block %d output: ", blockno);
// hexdump(outbuf + blockno*sizeof(block), 16);
}
}
// CBC mode encryption
void my_aes_encrypt(u8 *iv, u8 *inbuf, u8 *outbuf, unsigned long long len) {
u8 block[16];
unsigned int blockno = 0, i;
// debug_printf("aes_decrypt(%p, %p, %p, %lld)\n", iv, inbuf, outbuf, len);
for (blockno = 0; blockno <= (len / sizeof(block)); blockno++) {
unsigned int fraction;
if (blockno == (len / sizeof(block))) { // last block
fraction = len % sizeof(block);
if (fraction == 0) break;
memset(block, 0, sizeof(block));
} else fraction = 16;
// debug_printf("block %d: fraction = %d\n", blockno, fraction);
memcpy(block, inbuf + blockno * sizeof(block), fraction);
for(i=0; i < fraction; i++)
block[i] = inbuf[blockno * sizeof(block) + i] ^ iv[i];
encrypt((char*)block);
memcpy(iv, block, sizeof(block));
memcpy(outbuf + blockno * sizeof(block), block, sizeof(block));
// debug_printf("Block %d output: ", blockno);
// hexdump(outbuf + blockno*sizeof(block), 16);
}
}