/* Rijndael Block Cipher - aes.c Written by Mike Scott 21st April 1999 mike@compapp.dcu.ie 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 #include #include */ #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,u8 *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>8)])^ ROTL16(ftable[(u8)(x[fi[m+1]]>>16)])^ ROTL24(ftable[(u8)(x[fi[m+2]]>>24)]); } t=x; x=y; y=t; /* swap pointers */ } /* Last Round - unroll if possible */ for (m=j=0;j>8)])^ ROTL16((u32)fbsub[(u8)(x[fi[m+1]]>>16)])^ ROTL24((u32)fbsub[(u8)(x[fi[m+2]]>>24)]); } for (i=j=0;i>8)])^ ROTL16(rtable[(u8)(x[ri[m+1]]>>16)])^ ROTL24(rtable[(u8)(x[ri[m+2]]>>24)]); } t=x; x=y; y=t; /* swap pointers */ } /* Last Round - unroll if possible */ for (m=j=0;j>8)])^ ROTL16((u32)rbsub[(u8)(x[ri[m+1]]>>16)])^ ROTL24((u32)rbsub[(u8)(x[ri[m+2]]>>24)]); } for (i=j=0;i