postgresql/contrib/pgcrypto/rijndael.c
2005-10-15 02:49:52 +00:00

688 lines
15 KiB
C

/* $OpenBSD: rijndael.c,v 1.6 2000/12/09 18:51:34 markus Exp $ */
/* $PostgreSQL: pgsql/contrib/pgcrypto/rijndael.c,v 1.12 2005/10/15 02:49:06 momjian Exp $ */
/* This is an independent implementation of the encryption algorithm: */
/* */
/* RIJNDAEL by Joan Daemen and Vincent Rijmen */
/* */
/* which is a candidate algorithm in the Advanced Encryption Standard */
/* programme of the US National Institute of Standards and Technology. */
/* */
/* Copyright in this implementation is held by Dr B R Gladman but I */
/* hereby give permission for its free direct or derivative use subject */
/* to acknowledgment of its origin and compliance with any conditions */
/* that the originators of the algorithm place on its exploitation. */
/* */
/* Dr Brian Gladman (gladman@seven77.demon.co.uk) 14th January 1999 */
/* Timing data for Rijndael (rijndael.c)
Algorithm: rijndael (rijndael.c)
128 bit key:
Key Setup: 305/1389 cycles (encrypt/decrypt)
Encrypt: 374 cycles = 68.4 mbits/sec
Decrypt: 352 cycles = 72.7 mbits/sec
Mean: 363 cycles = 70.5 mbits/sec
192 bit key:
Key Setup: 277/1595 cycles (encrypt/decrypt)
Encrypt: 439 cycles = 58.3 mbits/sec
Decrypt: 425 cycles = 60.2 mbits/sec
Mean: 432 cycles = 59.3 mbits/sec
256 bit key:
Key Setup: 374/1960 cycles (encrypt/decrypt)
Encrypt: 502 cycles = 51.0 mbits/sec
Decrypt: 498 cycles = 51.4 mbits/sec
Mean: 500 cycles = 51.2 mbits/sec
*/
#include "postgres.h"
#include <sys/param.h>
#include "px.h"
#include "rijndael.h"
/* sanity check */
#if !defined(BYTE_ORDER) || (BYTE_ORDER != LITTLE_ENDIAN && BYTE_ORDER != BIG_ENDIAN)
#error Define BYTE_ORDER to be equal to either LITTLE_ENDIAN or BIG_ENDIAN
#endif
#define PRE_CALC_TABLES
#define LARGE_TABLES
static void gen_tabs(void);
/* 3. Basic macros for speeding up generic operations */
/* Circular rotate of 32 bit values */
#define rotr(x,n) (((x) >> ((int)(n))) | ((x) << (32 - (int)(n))))
#define rotl(x,n) (((x) << ((int)(n))) | ((x) >> (32 - (int)(n))))
/* Invert byte order in a 32 bit variable */
#define bswap(x) ((rotl((x), 8) & 0x00ff00ff) | (rotr((x), 8) & 0xff00ff00))
/* Extract byte from a 32 bit quantity (little endian notation) */
#define byte(x,n) ((u1byte)((x) >> (8 * (n))))
#if BYTE_ORDER != LITTLE_ENDIAN
#define BYTE_SWAP
#endif
#ifdef BYTE_SWAP
#define io_swap(x) bswap(x)
#else
#define io_swap(x) (x)
#endif
#ifdef PRINT_TABS
#undef PRE_CALC_TABLES
#endif
#ifdef PRE_CALC_TABLES
#include "rijndael.tbl"
#define tab_gen 1
#else /* !PRE_CALC_TABLES */
static u1byte pow_tab[256];
static u1byte log_tab[256];
static u1byte sbx_tab[256];
static u1byte isb_tab[256];
static u4byte rco_tab[10];
static u4byte ft_tab[4][256];
static u4byte it_tab[4][256];
#ifdef LARGE_TABLES
static u4byte fl_tab[4][256];
static u4byte il_tab[4][256];
#endif
static u4byte tab_gen = 0;
#endif /* !PRE_CALC_TABLES */
#define ff_mult(a,b) ((a) && (b) ? pow_tab[(log_tab[a] + log_tab[b]) % 255] : 0)
#define f_rn(bo, bi, n, k) \
(bo)[n] = ft_tab[0][byte((bi)[n],0)] ^ \
ft_tab[1][byte((bi)[((n) + 1) & 3],1)] ^ \
ft_tab[2][byte((bi)[((n) + 2) & 3],2)] ^ \
ft_tab[3][byte((bi)[((n) + 3) & 3],3)] ^ *((k) + (n))
#define i_rn(bo, bi, n, k) \
(bo)[n] = it_tab[0][byte((bi)[n],0)] ^ \
it_tab[1][byte((bi)[((n) + 3) & 3],1)] ^ \
it_tab[2][byte((bi)[((n) + 2) & 3],2)] ^ \
it_tab[3][byte((bi)[((n) + 1) & 3],3)] ^ *((k) + (n))
#ifdef LARGE_TABLES
#define ls_box(x) \
( fl_tab[0][byte(x, 0)] ^ \
fl_tab[1][byte(x, 1)] ^ \
fl_tab[2][byte(x, 2)] ^ \
fl_tab[3][byte(x, 3)] )
#define f_rl(bo, bi, n, k) \
(bo)[n] = fl_tab[0][byte((bi)[n],0)] ^ \
fl_tab[1][byte((bi)[((n) + 1) & 3],1)] ^ \
fl_tab[2][byte((bi)[((n) + 2) & 3],2)] ^ \
fl_tab[3][byte((bi)[((n) + 3) & 3],3)] ^ *((k) + (n))
#define i_rl(bo, bi, n, k) \
(bo)[n] = il_tab[0][byte((bi)[n],0)] ^ \
il_tab[1][byte((bi)[((n) + 3) & 3],1)] ^ \
il_tab[2][byte((bi)[((n) + 2) & 3],2)] ^ \
il_tab[3][byte((bi)[((n) + 1) & 3],3)] ^ *((k) + (n))
#else
#define ls_box(x) \
((u4byte)sbx_tab[byte(x, 0)] << 0) ^ \
((u4byte)sbx_tab[byte(x, 1)] << 8) ^ \
((u4byte)sbx_tab[byte(x, 2)] << 16) ^ \
((u4byte)sbx_tab[byte(x, 3)] << 24)
#define f_rl(bo, bi, n, k) \
(bo)[n] = (u4byte)sbx_tab[byte((bi)[n],0)] ^ \
rotl(((u4byte)sbx_tab[byte((bi)[((n) + 1) & 3],1)]), 8) ^ \
rotl(((u4byte)sbx_tab[byte((bi)[((n) + 2) & 3],2)]), 16) ^ \
rotl(((u4byte)sbx_tab[byte((bi)[((n) + 3) & 3],3)]), 24) ^ *((k) + (n))
#define i_rl(bo, bi, n, k) \
(bo)[n] = (u4byte)isb_tab[byte((bi)[n],0)] ^ \
rotl(((u4byte)isb_tab[byte((bi)[((n) + 3) & 3],1)]), 8) ^ \
rotl(((u4byte)isb_tab[byte((bi)[((n) + 2) & 3],2)]), 16) ^ \
rotl(((u4byte)isb_tab[byte((bi)[((n) + 1) & 3],3)]), 24) ^ *((k) + (n))
#endif
static void
gen_tabs(void)
{
#ifndef PRE_CALC_TABLES
u4byte i,
t;
u1byte p,
q;
/* log and power tables for GF(2**8) finite field with */
/* 0x11b as modular polynomial - the simplest prmitive */
/* root is 0x11, used here to generate the tables */
for (i = 0, p = 1; i < 256; ++i)
{
pow_tab[i] = (u1byte) p;
log_tab[p] = (u1byte) i;
p = p ^ (p << 1) ^ (p & 0x80 ? 0x01b : 0);
}
log_tab[1] = 0;
p = 1;
for (i = 0; i < 10; ++i)
{
rco_tab[i] = p;
p = (p << 1) ^ (p & 0x80 ? 0x1b : 0);
}
/* note that the affine byte transformation matrix in */
/* rijndael specification is in big endian format with */
/* bit 0 as the most significant bit. In the remainder */
/* of the specification the bits are numbered from the */
/* least significant end of a byte. */
for (i = 0; i < 256; ++i)
{
p = (i ? pow_tab[255 - log_tab[i]] : 0);
q = p;
q = (q >> 7) | (q << 1);
p ^= q;
q = (q >> 7) | (q << 1);
p ^= q;
q = (q >> 7) | (q << 1);
p ^= q;
q = (q >> 7) | (q << 1);
p ^= q ^ 0x63;
sbx_tab[i] = (u1byte) p;
isb_tab[p] = (u1byte) i;
}
for (i = 0; i < 256; ++i)
{
p = sbx_tab[i];
#ifdef LARGE_TABLES
t = p;
fl_tab[0][i] = t;
fl_tab[1][i] = rotl(t, 8);
fl_tab[2][i] = rotl(t, 16);
fl_tab[3][i] = rotl(t, 24);
#endif
t = ((u4byte) ff_mult(2, p)) |
((u4byte) p << 8) |
((u4byte) p << 16) |
((u4byte) ff_mult(3, p) << 24);
ft_tab[0][i] = t;
ft_tab[1][i] = rotl(t, 8);
ft_tab[2][i] = rotl(t, 16);
ft_tab[3][i] = rotl(t, 24);
p = isb_tab[i];
#ifdef LARGE_TABLES
t = p;
il_tab[0][i] = t;
il_tab[1][i] = rotl(t, 8);
il_tab[2][i] = rotl(t, 16);
il_tab[3][i] = rotl(t, 24);
#endif
t = ((u4byte) ff_mult(14, p)) |
((u4byte) ff_mult(9, p) << 8) |
((u4byte) ff_mult(13, p) << 16) |
((u4byte) ff_mult(11, p) << 24);
it_tab[0][i] = t;
it_tab[1][i] = rotl(t, 8);
it_tab[2][i] = rotl(t, 16);
it_tab[3][i] = rotl(t, 24);
}
tab_gen = 1;
#endif /* !PRE_CALC_TABLES */
}
#define star_x(x) (((x) & 0x7f7f7f7f) << 1) ^ ((((x) & 0x80808080) >> 7) * 0x1b)
#define imix_col(y,x) \
do { \
u = star_x(x); \
v = star_x(u); \
w = star_x(v); \
t = w ^ (x); \
(y) = u ^ v ^ w; \
(y) ^= rotr(u ^ t, 8) ^ \
rotr(v ^ t, 16) ^ \
rotr(t,24); \
} while (0)
/* initialise the key schedule from the user supplied key */
#define loop4(i) \
do { t = ls_box(rotr(t, 8)) ^ rco_tab[i]; \
t ^= e_key[4 * i]; e_key[4 * i + 4] = t; \
t ^= e_key[4 * i + 1]; e_key[4 * i + 5] = t; \
t ^= e_key[4 * i + 2]; e_key[4 * i + 6] = t; \
t ^= e_key[4 * i + 3]; e_key[4 * i + 7] = t; \
} while (0)
#define loop6(i) \
do { t = ls_box(rotr(t, 8)) ^ rco_tab[i]; \
t ^= e_key[6 * (i)]; e_key[6 * (i) + 6] = t; \
t ^= e_key[6 * (i) + 1]; e_key[6 * (i) + 7] = t; \
t ^= e_key[6 * (i) + 2]; e_key[6 * (i) + 8] = t; \
t ^= e_key[6 * (i) + 3]; e_key[6 * (i) + 9] = t; \
t ^= e_key[6 * (i) + 4]; e_key[6 * (i) + 10] = t; \
t ^= e_key[6 * (i) + 5]; e_key[6 * (i) + 11] = t; \
} while (0)
#define loop8(i) \
do { t = ls_box(rotr(t, 8)) ^ rco_tab[i]; \
t ^= e_key[8 * (i)]; e_key[8 * (i) + 8] = t; \
t ^= e_key[8 * (i) + 1]; e_key[8 * (i) + 9] = t; \
t ^= e_key[8 * (i) + 2]; e_key[8 * (i) + 10] = t; \
t ^= e_key[8 * (i) + 3]; e_key[8 * (i) + 11] = t; \
t = e_key[8 * (i) + 4] ^ ls_box(t); \
e_key[8 * (i) + 12] = t; \
t ^= e_key[8 * (i) + 5]; e_key[8 * (i) + 13] = t; \
t ^= e_key[8 * (i) + 6]; e_key[8 * (i) + 14] = t; \
t ^= e_key[8 * (i) + 7]; e_key[8 * (i) + 15] = t; \
} while (0)
rijndael_ctx *
rijndael_set_key(rijndael_ctx * ctx, const u4byte * in_key, const u4byte key_len,
int encrypt)
{
u4byte i,
t,
u,
v,
w;
u4byte *e_key = ctx->e_key;
u4byte *d_key = ctx->d_key;
ctx->decrypt = !encrypt;
if (!tab_gen)
gen_tabs();
ctx->k_len = (key_len + 31) / 32;
e_key[0] = io_swap(in_key[0]);
e_key[1] = io_swap(in_key[1]);
e_key[2] = io_swap(in_key[2]);
e_key[3] = io_swap(in_key[3]);
switch (ctx->k_len)
{
case 4:
t = e_key[3];
for (i = 0; i < 10; ++i)
loop4(i);
break;
case 6:
e_key[4] = io_swap(in_key[4]);
t = e_key[5] = io_swap(in_key[5]);
for (i = 0; i < 8; ++i)
loop6(i);
break;
case 8:
e_key[4] = io_swap(in_key[4]);
e_key[5] = io_swap(in_key[5]);
e_key[6] = io_swap(in_key[6]);
t = e_key[7] = io_swap(in_key[7]);
for (i = 0; i < 7; ++i)
loop8(i);
break;
}
if (!encrypt)
{
d_key[0] = e_key[0];
d_key[1] = e_key[1];
d_key[2] = e_key[2];
d_key[3] = e_key[3];
for (i = 4; i < 4 * ctx->k_len + 24; ++i)
imix_col(d_key[i], e_key[i]);
}
return ctx;
}
/* encrypt a block of text */
#define f_nround(bo, bi, k) \
do { \
f_rn(bo, bi, 0, k); \
f_rn(bo, bi, 1, k); \
f_rn(bo, bi, 2, k); \
f_rn(bo, bi, 3, k); \
k += 4; \
} while (0)
#define f_lround(bo, bi, k) \
do { \
f_rl(bo, bi, 0, k); \
f_rl(bo, bi, 1, k); \
f_rl(bo, bi, 2, k); \
f_rl(bo, bi, 3, k); \
} while (0)
void
rijndael_encrypt(rijndael_ctx * ctx, const u4byte * in_blk, u4byte * out_blk)
{
u4byte k_len = ctx->k_len;
u4byte *e_key = ctx->e_key;
u4byte b0[4],
b1[4],
*kp;
b0[0] = io_swap(in_blk[0]) ^ e_key[0];
b0[1] = io_swap(in_blk[1]) ^ e_key[1];
b0[2] = io_swap(in_blk[2]) ^ e_key[2];
b0[3] = io_swap(in_blk[3]) ^ e_key[3];
kp = e_key + 4;
if (k_len > 6)
{
f_nround(b1, b0, kp);
f_nround(b0, b1, kp);
}
if (k_len > 4)
{
f_nround(b1, b0, kp);
f_nround(b0, b1, kp);
}
f_nround(b1, b0, kp);
f_nround(b0, b1, kp);
f_nround(b1, b0, kp);
f_nround(b0, b1, kp);
f_nround(b1, b0, kp);
f_nround(b0, b1, kp);
f_nround(b1, b0, kp);
f_nround(b0, b1, kp);
f_nround(b1, b0, kp);
f_lround(b0, b1, kp);
out_blk[0] = io_swap(b0[0]);
out_blk[1] = io_swap(b0[1]);
out_blk[2] = io_swap(b0[2]);
out_blk[3] = io_swap(b0[3]);
}
/* decrypt a block of text */
#define i_nround(bo, bi, k) \
do { \
i_rn(bo, bi, 0, k); \
i_rn(bo, bi, 1, k); \
i_rn(bo, bi, 2, k); \
i_rn(bo, bi, 3, k); \
k -= 4; \
} while (0)
#define i_lround(bo, bi, k) \
do { \
i_rl(bo, bi, 0, k); \
i_rl(bo, bi, 1, k); \
i_rl(bo, bi, 2, k); \
i_rl(bo, bi, 3, k); \
} while (0)
void
rijndael_decrypt(rijndael_ctx * ctx, const u4byte * in_blk, u4byte * out_blk)
{
u4byte b0[4],
b1[4],
*kp;
u4byte k_len = ctx->k_len;
u4byte *e_key = ctx->e_key;
u4byte *d_key = ctx->d_key;
b0[0] = io_swap(in_blk[0]) ^ e_key[4 * k_len + 24];
b0[1] = io_swap(in_blk[1]) ^ e_key[4 * k_len + 25];
b0[2] = io_swap(in_blk[2]) ^ e_key[4 * k_len + 26];
b0[3] = io_swap(in_blk[3]) ^ e_key[4 * k_len + 27];
kp = d_key + 4 * (k_len + 5);
if (k_len > 6)
{
i_nround(b1, b0, kp);
i_nround(b0, b1, kp);
}
if (k_len > 4)
{
i_nround(b1, b0, kp);
i_nround(b0, b1, kp);
}
i_nround(b1, b0, kp);
i_nround(b0, b1, kp);
i_nround(b1, b0, kp);
i_nround(b0, b1, kp);
i_nround(b1, b0, kp);
i_nround(b0, b1, kp);
i_nround(b1, b0, kp);
i_nround(b0, b1, kp);
i_nround(b1, b0, kp);
i_lround(b0, b1, kp);
out_blk[0] = io_swap(b0[0]);
out_blk[1] = io_swap(b0[1]);
out_blk[2] = io_swap(b0[2]);
out_blk[3] = io_swap(b0[3]);
}
/*
* conventional interface
*
* ATM it hopes all data is 4-byte aligned - which
* should be true for PX. -marko
*/
void
aes_set_key(rijndael_ctx * ctx, const uint8 *key, unsigned keybits, int enc)
{
uint32 *k;
k = (uint32 *) key;
rijndael_set_key(ctx, k, keybits, enc);
}
void
aes_ecb_encrypt(rijndael_ctx * ctx, uint8 *data, unsigned len)
{
unsigned bs = 16;
uint32 *d;
while (len >= bs)
{
d = (uint32 *) data;
rijndael_encrypt(ctx, d, d);
len -= bs;
data += bs;
}
}
void
aes_ecb_decrypt(rijndael_ctx * ctx, uint8 *data, unsigned len)
{
unsigned bs = 16;
uint32 *d;
while (len >= bs)
{
d = (uint32 *) data;
rijndael_decrypt(ctx, d, d);
len -= bs;
data += bs;
}
}
void
aes_cbc_encrypt(rijndael_ctx * ctx, uint8 *iva, uint8 *data, unsigned len)
{
uint32 *iv = (uint32 *) iva;
uint32 *d = (uint32 *) data;
unsigned bs = 16;
while (len >= bs)
{
d[0] ^= iv[0];
d[1] ^= iv[1];
d[2] ^= iv[2];
d[3] ^= iv[3];
rijndael_encrypt(ctx, d, d);
iv = d;
d += bs / 4;
len -= bs;
}
}
void
aes_cbc_decrypt(rijndael_ctx * ctx, uint8 *iva, uint8 *data, unsigned len)
{
uint32 *d = (uint32 *) data;
unsigned bs = 16;
uint32 buf[4],
iv[4];
memcpy(iv, iva, bs);
while (len >= bs)
{
buf[0] = d[0];
buf[1] = d[1];
buf[2] = d[2];
buf[3] = d[3];
rijndael_decrypt(ctx, buf, d);
d[0] ^= iv[0];
d[1] ^= iv[1];
d[2] ^= iv[2];
d[3] ^= iv[3];
iv[0] = buf[0];
iv[1] = buf[1];
iv[2] = buf[2];
iv[3] = buf[3];
d += 4;
len -= bs;
}
}
/*
* pre-calculate tables.
*
* On i386 lifts 17k from .bss to .rodata
* and avoids 1k code and setup time.
* -marko
*/
#ifdef PRINT_TABS
static void
show256u8(char *name, uint8 *data)
{
int i;
printf("static const u1byte %s[256] = {\n ", name);
for (i = 0; i < 256;)
{
printf("%u", pow_tab[i++]);
if (i < 256)
printf(i % 16 ? ", " : ",\n ");
}
printf("\n};\n\n");
}
static void
show4x256u32(char *name, uint32 data[4][256])
{
int i,
j;
printf("static const u4byte %s[4][256] = {\n{\n ", name);
for (i = 0; i < 4; i++)
{
for (j = 0; j < 256;)
{
printf("0x%08x", data[i][j]);
j++;
if (j < 256)
printf(j % 4 ? ", " : ",\n ");
}
printf(i < 3 ? "\n}, {\n " : "\n}\n");
}
printf("};\n\n");
}
int
main()
{
int i;
char *hdr = "/* Generated by rijndael.c */\n\n";
gen_tabs();
printf(hdr);
show256u8("pow_tab", pow_tab);
show256u8("log_tab", log_tab);
show256u8("sbx_tab", sbx_tab);
show256u8("isb_tab", isb_tab);
show4x256u32("ft_tab", ft_tab);
show4x256u32("it_tab", it_tab);
#ifdef LARGE_TABLES
show4x256u32("fl_tab", fl_tab);
show4x256u32("il_tab", il_tab);
#endif
printf("static const u4byte rco_tab[10] = {\n ");
for (i = 0; i < 10; i++)
{
printf("0x%08x", rco_tab[i]);
if (i < 9)
printf(", ");
if (i == 4)
printf("\n ");
}
printf("\n};\n\n");
return 0;
}
#endif