*
* Based on code:
*
- * Copyright (c) 1995 - 2000 Kungliga Tekniska Högskolan
+ * Copyright (c) 1995 - 2000 Kungliga Tekniska Högskolan
* (Royal Institute of Technology, Stockholm, Sweden).
* All rights reserved.
*
#define ROUNDS 16
struct fcrypt_ctx {
- u32 sched[ROUNDS];
+ __be32 sched[ROUNDS];
};
/* Rotate right two 32 bit numbers as a 56 bit number */
u32 t = lo & ((1 << n) - 1); \
lo = (lo >> n) | ((hi & ((1 << n) - 1)) << (32 - n)); \
hi = (hi >> n) | (t << (24-n)); \
-} while(0)
+} while (0)
/* Rotate right one 64 bit number as a 56 bit number */
#define ror56_64(k, n) \
do { \
k = (k >> n) | ((k & ((1 << n) - 1)) << (56 - n)); \
-} while(0)
+} while (0)
/*
* Sboxes for Feistel network derived from
* /afs/transarc.com/public/afsps/afs.rel31b.export-src/rxkad/sboxes.h
*/
#undef Z
-#define Z(x) __constant_be32_to_cpu(x << 3)
-static const u32 sbox0[256] = {
+#define Z(x) cpu_to_be32(x << 3)
+static const __be32 sbox0[256] = {
Z(0xea), Z(0x7f), Z(0xb2), Z(0x64), Z(0x9d), Z(0xb0), Z(0xd9), Z(0x11),
Z(0xcd), Z(0x86), Z(0x86), Z(0x91), Z(0x0a), Z(0xb2), Z(0x93), Z(0x06),
Z(0x0e), Z(0x06), Z(0xd2), Z(0x65), Z(0x73), Z(0xc5), Z(0x28), Z(0x60),
};
#undef Z
-#define Z(x) __constant_be32_to_cpu((x << 27) | (x >> 5))
-static const u32 sbox1[256] = {
+#define Z(x) cpu_to_be32((x << 27) | (x >> 5))
+static const __be32 sbox1[256] = {
Z(0x77), Z(0x14), Z(0xa6), Z(0xfe), Z(0xb2), Z(0x5e), Z(0x8c), Z(0x3e),
Z(0x67), Z(0x6c), Z(0xa1), Z(0x0d), Z(0xc2), Z(0xa2), Z(0xc1), Z(0x85),
Z(0x6c), Z(0x7b), Z(0x67), Z(0xc6), Z(0x23), Z(0xe3), Z(0xf2), Z(0x89),
};
#undef Z
-#define Z(x) __constant_be32_to_cpu(x << 11)
-static const u32 sbox2[256] = {
+#define Z(x) cpu_to_be32(x << 11)
+static const __be32 sbox2[256] = {
Z(0xf0), Z(0x37), Z(0x24), Z(0x53), Z(0x2a), Z(0x03), Z(0x83), Z(0x86),
Z(0xd1), Z(0xec), Z(0x50), Z(0xf0), Z(0x42), Z(0x78), Z(0x2f), Z(0x6d),
Z(0xbf), Z(0x80), Z(0x87), Z(0x27), Z(0x95), Z(0xe2), Z(0xc5), Z(0x5d),
};
#undef Z
-#define Z(x) __constant_be32_to_cpu(x << 19)
-static const u32 sbox3[256] = {
+#define Z(x) cpu_to_be32(x << 19)
+static const __be32 sbox3[256] = {
Z(0xa9), Z(0x2a), Z(0x48), Z(0x51), Z(0x84), Z(0x7e), Z(0x49), Z(0xe2),
Z(0xb5), Z(0xb7), Z(0x42), Z(0x33), Z(0x7d), Z(0x5d), Z(0xa6), Z(0x12),
Z(0x44), Z(0x48), Z(0x6d), Z(0x28), Z(0xaa), Z(0x20), Z(0x6d), Z(0x57),
*/
#define F_ENCRYPT(R, L, sched) \
do { \
- union lc4 { u32 l; u8 c[4]; } u; \
+ union lc4 { __be32 l; u8 c[4]; } u; \
u.l = sched ^ R; \
L ^= sbox0[u.c[0]] ^ sbox1[u.c[1]] ^ sbox2[u.c[2]] ^ sbox3[u.c[3]]; \
-} while(0)
+} while (0)
/*
* encryptor
{
const struct fcrypt_ctx *ctx = crypto_tfm_ctx(tfm);
struct {
- u32 l, r;
+ __be32 l, r;
} X;
memcpy(&X, src, sizeof(X));
{
const struct fcrypt_ctx *ctx = crypto_tfm_ctx(tfm);
struct {
- u32 l, r;
+ __be32 l, r;
} X;
memcpy(&X, src, sizeof(X));
k |= (*key) >> 1;
/* Use lower 32 bits for schedule, rotate by 11 each round (16 times) */
- ctx->sched[0x0] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x1] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x2] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x3] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x4] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x5] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x6] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x7] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x8] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0x9] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0xa] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0xb] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0xc] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0xd] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0xe] = be32_to_cpu(k); ror56_64(k, 11);
- ctx->sched[0xf] = be32_to_cpu(k);
+ ctx->sched[0x0] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x1] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x2] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x3] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x4] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x5] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x6] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x7] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x8] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0x9] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0xa] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0xb] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0xc] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0xd] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0xe] = cpu_to_be32(k); ror56_64(k, 11);
+ ctx->sched[0xf] = cpu_to_be32(k);
return 0;
#else
lo |= (*key) >> 1;
/* Use lower 32 bits for schedule, rotate by 11 each round (16 times) */
- ctx->sched[0x0] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x1] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x2] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x3] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x4] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x5] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x6] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x7] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x8] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0x9] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0xa] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0xb] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0xc] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0xd] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0xe] = be32_to_cpu(lo); ror56(hi, lo, 11);
- ctx->sched[0xf] = be32_to_cpu(lo);
+ ctx->sched[0x0] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x1] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x2] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x3] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x4] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x5] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x6] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x7] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x8] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0x9] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0xa] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0xb] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0xc] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0xd] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0xe] = cpu_to_be32(lo); ror56(hi, lo, 11);
+ ctx->sched[0xf] = cpu_to_be32(lo);
return 0;
#endif
}
.cia_decrypt = fcrypt_decrypt } }
};
-static int __init init(void)
+static int __init fcrypt_mod_init(void)
{
return crypto_register_alg(&fcrypt_alg);
}
-static void __exit fini(void)
+static void __exit fcrypt_mod_fini(void)
{
crypto_unregister_alg(&fcrypt_alg);
}
-module_init(init);
-module_exit(fini);
+module_init(fcrypt_mod_init);
+module_exit(fcrypt_mod_fini);
MODULE_LICENSE("Dual BSD/GPL");
MODULE_DESCRIPTION("FCrypt Cipher Algorithm");
git://ftp.safe.ca / safe / jmp / linux-2.6 / blobdiff