diff options
Diffstat (limited to 'src/plugins/crypto_native/aes_gcm.c')
-rw-r--r-- | src/plugins/crypto_native/aes_gcm.c | 274 |
1 files changed, 114 insertions, 160 deletions
diff --git a/src/plugins/crypto_native/aes_gcm.c b/src/plugins/crypto_native/aes_gcm.c index 554fb2b2699..f2dec629359 100644 --- a/src/plugins/crypto_native/aes_gcm.c +++ b/src/plugins/crypto_native/aes_gcm.c @@ -30,113 +30,74 @@ typedef struct { /* pre-calculated hash key values */ - const __m128i Hi[8]; + const u8x16 Hi[8]; /* extracted AES key */ - const __m128i Ke[15]; + const u8x16 Ke[15]; } aes_gcm_key_data_t; -static const __m128i last_byte_one = { 0, 1ULL << 56 }; -static const __m128i zero = { 0, 0 }; +static const u32x4 last_byte_one = { 0, 0, 0, 1 << 24 }; static const u8x16 bswap_mask = { 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0 }; -static const u8x16 byte_mask_scale = { - 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 -}; - -static_always_inline __m128i -aesni_gcm_bswap (__m128i x) -{ - return _mm_shuffle_epi8 (x, (__m128i) bswap_mask); -} - -static_always_inline __m128i -aesni_gcm_byte_mask (__m128i x, u8 n_bytes) -{ - u8x16 mask = u8x16_is_greater (u8x16_splat (n_bytes), byte_mask_scale); - - return _mm_blendv_epi8 (zero, x, (__m128i) mask); -} - -static_always_inline __m128i -aesni_gcm_load_partial (__m128i * p, int n_bytes) -{ - ASSERT (n_bytes <= 16); -#ifdef __AVX512F__ - return _mm_mask_loadu_epi8 (zero, (1 << n_bytes) - 1, p); -#else - return aesni_gcm_byte_mask (CLIB_MEM_OVERFLOW_LOAD (_mm_loadu_si128, p), - n_bytes); -#endif -} - -static_always_inline void -aesni_gcm_store_partial (void *p, __m128i r, int n_bytes) +static_always_inline u8x16 +aesni_gcm_bswap (u8x16 x) { -#ifdef __AVX512F__ - _mm_mask_storeu_epi8 (p, (1 << n_bytes) - 1, r); -#else - u8x16 mask = u8x16_is_greater (u8x16_splat (n_bytes), byte_mask_scale); - _mm_maskmoveu_si128 (r, (__m128i) mask, p); -#endif + return (u8x16) _mm_shuffle_epi8 ((__m128i) x, (__m128i) bswap_mask); } static_always_inline void -aesni_gcm_load (__m128i * d, __m128i * inv, int n, int n_bytes) +aesni_gcm_load (u8x16 * d, u8x16u * inv, int n, int n_bytes) { for (int i = 0; i < n - 1; i++) - d[i] = _mm_loadu_si128 (inv + i); - d[n - 1] = n_bytes ? aesni_gcm_load_partial (inv + n - 1, n_bytes) : - _mm_loadu_si128 (inv + n - 1); + d[i] = inv[i]; + d[n - 1] = n_bytes ? aes_load_partial (inv + n - 1, n_bytes) : inv[n - 1]; } static_always_inline void -aesni_gcm_store (__m128i * d, __m128i * outv, int n, int n_bytes) +aesni_gcm_store (u8x16 * d, u8x16u * outv, int n, int n_bytes) { for (int i = 0; i < n - 1; i++) - _mm_storeu_si128 (outv + i, d[i]); + outv[i] = d[i]; if (n_bytes & 0xf) - aesni_gcm_store_partial (outv + n - 1, d[n - 1], n_bytes); + aes_store_partial (outv + n - 1, d[n - 1], n_bytes); else - _mm_storeu_si128 (outv + n - 1, d[n - 1]); + outv[n - 1] = d[n - 1]; } static_always_inline void -aesni_gcm_enc_first_round (__m128i * r, __m128i * Y, u32 * ctr, __m128i k, +aesni_gcm_enc_first_round (u8x16 * r, u32x4 * Y, u32 * ctr, u8x16 k, int n_blocks) { - u32 i; - if (PREDICT_TRUE ((u8) ctr[0] < (256 - n_blocks))) { - for (i = 0; i < n_blocks; i++) + for (int i = 0; i < n_blocks; i++) { - Y[0] = _mm_add_epi32 (Y[0], last_byte_one); - r[i] = k ^ Y[0]; + Y[0] += last_byte_one; + r[i] = k ^ (u8x16) Y[0]; } ctr[0] += n_blocks; } else { - for (i = 0; i < n_blocks; i++) + for (int i = 0; i < n_blocks; i++) { - Y[0] = _mm_insert_epi32 (Y[0], clib_host_to_net_u32 (++ctr[0]), 3); - r[i] = k ^ Y[0]; + Y[0][3] = clib_host_to_net_u32 (++ctr[0]); + r[i] = k ^ (u8x16) Y[0]; } } } static_always_inline void -aesni_gcm_enc_round (__m128i * r, __m128i k, int n_blocks) +aesni_gcm_enc_round (u8x16 * r, u8x16 k, int n_blocks) { for (int i = 0; i < n_blocks; i++) - r[i] = _mm_aesenc_si128 (r[i], k); + r[i] = aes_enc_round (r[i], k); } static_always_inline void -aesni_gcm_enc_last_round (__m128i * r, __m128i * d, const __m128i * k, +aesni_gcm_enc_last_round (u8x16 * r, u8x16 * d, u8x16 const *k, int rounds, int n_blocks) { @@ -145,26 +106,25 @@ aesni_gcm_enc_last_round (__m128i * r, __m128i * d, const __m128i * k, aesni_gcm_enc_round (r, k[i], n_blocks); for (int i = 0; i < n_blocks; i++) - d[i] ^= _mm_aesenclast_si128 (r[i], k[rounds]); + d[i] ^= aes_enc_last_round (r[i], k[rounds]); } -static_always_inline __m128i -aesni_gcm_ghash_blocks (__m128i T, aes_gcm_key_data_t * kd, - const __m128i * in, int n_blocks) +static_always_inline u8x16 +aesni_gcm_ghash_blocks (u8x16 T, aes_gcm_key_data_t * kd, + u8x16u * in, int n_blocks) { ghash_data_t _gd, *gd = &_gd; - const __m128i *Hi = kd->Hi + n_blocks - 1; - ghash_mul_first (gd, aesni_gcm_bswap (_mm_loadu_si128 (in)) ^ T, Hi[0]); + const u8x16 *Hi = kd->Hi + n_blocks - 1; + ghash_mul_first (gd, aesni_gcm_bswap (in[0]) ^ T, Hi[0]); for (int i = 1; i < n_blocks; i++) - ghash_mul_next (gd, aesni_gcm_bswap (_mm_loadu_si128 (in + i)), Hi[-i]); + ghash_mul_next (gd, aesni_gcm_bswap ((in[i])), Hi[-i]); ghash_reduce (gd); ghash_reduce2 (gd); return ghash_final (gd); } -static_always_inline __m128i -aesni_gcm_ghash (__m128i T, aes_gcm_key_data_t * kd, const __m128i * in, - u32 n_left) +static_always_inline u8x16 +aesni_gcm_ghash (u8x16 T, aes_gcm_key_data_t * kd, u8x16u * in, u32 n_left) { while (n_left >= 128) @@ -197,28 +157,28 @@ aesni_gcm_ghash (__m128i T, aes_gcm_key_data_t * kd, const __m128i * in, if (n_left) { - __m128i r = aesni_gcm_load_partial ((__m128i *) in, n_left); + u8x16 r = aes_load_partial (in, n_left); T = ghash_mul (aesni_gcm_bswap (r) ^ T, kd->Hi[0]); } return T; } -static_always_inline __m128i -aesni_gcm_calc (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, - __m128i * Y, u32 * ctr, __m128i * inv, __m128i * outv, +static_always_inline u8x16 +aesni_gcm_calc (u8x16 T, aes_gcm_key_data_t * kd, u8x16 * d, + u32x4 * Y, u32 * ctr, u8x16u * inv, u8x16u * outv, int rounds, int n, int last_block_bytes, int with_ghash, int is_encrypt) { - __m128i r[n]; + u8x16 r[n]; ghash_data_t _gd = { }, *gd = &_gd; - const __m128i *k = kd->Ke; + const u8x16 *rk = (u8x16 *) kd->Ke; int hidx = is_encrypt ? 4 : n, didx = 0; _mm_prefetch (inv + 4, _MM_HINT_T0); /* AES rounds 0 and 1 */ - aesni_gcm_enc_first_round (r, Y, ctr, k[0], n); - aesni_gcm_enc_round (r, k[1], n); + aesni_gcm_enc_first_round (r, Y, ctr, rk[0], n); + aesni_gcm_enc_round (r, rk[1], n); /* load data - decrypt round */ if (is_encrypt == 0) @@ -229,32 +189,32 @@ aesni_gcm_calc (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, ghash_mul_first (gd, aesni_gcm_bswap (d[didx++]) ^ T, kd->Hi[--hidx]); /* AES rounds 2 and 3 */ - aesni_gcm_enc_round (r, k[2], n); - aesni_gcm_enc_round (r, k[3], n); + aesni_gcm_enc_round (r, rk[2], n); + aesni_gcm_enc_round (r, rk[3], n); /* GHASH multiply block 2 */ if (with_ghash && hidx) ghash_mul_next (gd, aesni_gcm_bswap (d[didx++]), kd->Hi[--hidx]); /* AES rounds 4 and 5 */ - aesni_gcm_enc_round (r, k[4], n); - aesni_gcm_enc_round (r, k[5], n); + aesni_gcm_enc_round (r, rk[4], n); + aesni_gcm_enc_round (r, rk[5], n); /* GHASH multiply block 3 */ if (with_ghash && hidx) ghash_mul_next (gd, aesni_gcm_bswap (d[didx++]), kd->Hi[--hidx]); /* AES rounds 6 and 7 */ - aesni_gcm_enc_round (r, k[6], n); - aesni_gcm_enc_round (r, k[7], n); + aesni_gcm_enc_round (r, rk[6], n); + aesni_gcm_enc_round (r, rk[7], n); /* GHASH multiply block 4 */ if (with_ghash && hidx) ghash_mul_next (gd, aesni_gcm_bswap (d[didx++]), kd->Hi[--hidx]); /* AES rounds 8 and 9 */ - aesni_gcm_enc_round (r, k[8], n); - aesni_gcm_enc_round (r, k[9], n); + aesni_gcm_enc_round (r, rk[8], n); + aesni_gcm_enc_round (r, rk[9], n); /* GHASH reduce 1st step */ if (with_ghash) @@ -269,7 +229,7 @@ aesni_gcm_calc (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, ghash_reduce2 (gd); /* AES last round(s) */ - aesni_gcm_enc_last_round (r, d, k, rounds, n); + aesni_gcm_enc_last_round (r, d, rk, rounds, n); /* store data */ aesni_gcm_store (d, outv, n, last_block_bytes); @@ -281,18 +241,18 @@ aesni_gcm_calc (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, return T; } -static_always_inline __m128i -aesni_gcm_calc_double (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, - __m128i * Y, u32 * ctr, __m128i * inv, __m128i * outv, +static_always_inline u8x16 +aesni_gcm_calc_double (u8x16 T, aes_gcm_key_data_t * kd, u8x16 * d, + u32x4 * Y, u32 * ctr, u8x16u * inv, u8x16u * outv, int rounds, int is_encrypt) { - __m128i r[4]; + u8x16 r[4]; ghash_data_t _gd, *gd = &_gd; - const __m128i *k = kd->Ke; + const u8x16 *rk = (u8x16 *) kd->Ke; /* AES rounds 0 and 1 */ - aesni_gcm_enc_first_round (r, Y, ctr, k[0], 4); - aesni_gcm_enc_round (r, k[1], 4); + aesni_gcm_enc_first_round (r, Y, ctr, rk[0], 4); + aesni_gcm_enc_round (r, rk[1], 4); /* load 4 blocks of data - decrypt round */ if (is_encrypt == 0) @@ -302,36 +262,36 @@ aesni_gcm_calc_double (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, ghash_mul_first (gd, aesni_gcm_bswap (d[0]) ^ T, kd->Hi[7]); /* AES rounds 2 and 3 */ - aesni_gcm_enc_round (r, k[2], 4); - aesni_gcm_enc_round (r, k[3], 4); + aesni_gcm_enc_round (r, rk[2], 4); + aesni_gcm_enc_round (r, rk[3], 4); /* GHASH multiply block 1 */ ghash_mul_next (gd, aesni_gcm_bswap (d[1]), kd->Hi[6]); /* AES rounds 4 and 5 */ - aesni_gcm_enc_round (r, k[4], 4); - aesni_gcm_enc_round (r, k[5], 4); + aesni_gcm_enc_round (r, rk[4], 4); + aesni_gcm_enc_round (r, rk[5], 4); /* GHASH multiply block 2 */ ghash_mul_next (gd, aesni_gcm_bswap (d[2]), kd->Hi[5]); /* AES rounds 6 and 7 */ - aesni_gcm_enc_round (r, k[6], 4); - aesni_gcm_enc_round (r, k[7], 4); + aesni_gcm_enc_round (r, rk[6], 4); + aesni_gcm_enc_round (r, rk[7], 4); /* GHASH multiply block 3 */ ghash_mul_next (gd, aesni_gcm_bswap (d[3]), kd->Hi[4]); /* AES rounds 8 and 9 */ - aesni_gcm_enc_round (r, k[8], 4); - aesni_gcm_enc_round (r, k[9], 4); + aesni_gcm_enc_round (r, rk[8], 4); + aesni_gcm_enc_round (r, rk[9], 4); /* load 4 blocks of data - encrypt round */ if (is_encrypt) aesni_gcm_load (d, inv, 4, 0); /* AES last round(s) */ - aesni_gcm_enc_last_round (r, d, k, rounds, 4); + aesni_gcm_enc_last_round (r, d, rk, rounds, 4); /* store 4 blocks of data */ aesni_gcm_store (d, outv, 4, 0); @@ -344,36 +304,36 @@ aesni_gcm_calc_double (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, ghash_mul_next (gd, aesni_gcm_bswap (d[0]), kd->Hi[3]); /* AES rounds 0, 1 and 2 */ - aesni_gcm_enc_first_round (r, Y, ctr, k[0], 4); - aesni_gcm_enc_round (r, k[1], 4); - aesni_gcm_enc_round (r, k[2], 4); + aesni_gcm_enc_first_round (r, Y, ctr, rk[0], 4); + aesni_gcm_enc_round (r, rk[1], 4); + aesni_gcm_enc_round (r, rk[2], 4); /* GHASH multiply block 5 */ ghash_mul_next (gd, aesni_gcm_bswap (d[1]), kd->Hi[2]); /* AES rounds 3 and 4 */ - aesni_gcm_enc_round (r, k[3], 4); - aesni_gcm_enc_round (r, k[4], 4); + aesni_gcm_enc_round (r, rk[3], 4); + aesni_gcm_enc_round (r, rk[4], 4); /* GHASH multiply block 6 */ ghash_mul_next (gd, aesni_gcm_bswap (d[2]), kd->Hi[1]); /* AES rounds 5 and 6 */ - aesni_gcm_enc_round (r, k[5], 4); - aesni_gcm_enc_round (r, k[6], 4); + aesni_gcm_enc_round (r, rk[5], 4); + aesni_gcm_enc_round (r, rk[6], 4); /* GHASH multiply block 7 */ ghash_mul_next (gd, aesni_gcm_bswap (d[3]), kd->Hi[0]); /* AES rounds 7 and 8 */ - aesni_gcm_enc_round (r, k[7], 4); - aesni_gcm_enc_round (r, k[8], 4); + aesni_gcm_enc_round (r, rk[7], 4); + aesni_gcm_enc_round (r, rk[8], 4); /* GHASH reduce 1st step */ ghash_reduce (gd); /* AES round 9 */ - aesni_gcm_enc_round (r, k[9], 4); + aesni_gcm_enc_round (r, rk[9], 4); /* load data - encrypt round */ if (is_encrypt) @@ -383,7 +343,7 @@ aesni_gcm_calc_double (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, ghash_reduce2 (gd); /* AES last round(s) */ - aesni_gcm_enc_last_round (r, d, k, rounds, 4); + aesni_gcm_enc_last_round (r, d, rk, rounds, 4); /* store data */ aesni_gcm_store (d, outv + 4, 4, 0); @@ -392,14 +352,14 @@ aesni_gcm_calc_double (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, return ghash_final (gd); } -static_always_inline __m128i -aesni_gcm_ghash_last (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, +static_always_inline u8x16 +aesni_gcm_ghash_last (u8x16 T, aes_gcm_key_data_t * kd, u8x16 * d, int n_blocks, int n_bytes) { ghash_data_t _gd, *gd = &_gd; if (n_bytes) - d[n_blocks - 1] = aesni_gcm_byte_mask (d[n_blocks - 1], n_bytes); + d[n_blocks - 1] = aes_byte_mask (d[n_blocks - 1], n_bytes); ghash_mul_first (gd, aesni_gcm_bswap (d[0]) ^ T, kd->Hi[n_blocks - 1]); if (n_blocks > 1) @@ -414,12 +374,11 @@ aesni_gcm_ghash_last (__m128i T, aes_gcm_key_data_t * kd, __m128i * d, } -static_always_inline __m128i -aesni_gcm_enc (__m128i T, aes_gcm_key_data_t * kd, __m128i Y, const u8 * in, - const u8 * out, u32 n_left, int rounds) +static_always_inline u8x16 +aesni_gcm_enc (u8x16 T, aes_gcm_key_data_t * kd, u32x4 Y, u8x16u * inv, + u8x16u * outv, u32 n_left, int rounds) { - __m128i *inv = (__m128i *) in, *outv = (__m128i *) out; - __m128i d[4]; + u8x16 d[4]; u32 ctr = 1; if (n_left == 0) @@ -520,12 +479,11 @@ aesni_gcm_enc (__m128i T, aes_gcm_key_data_t * kd, __m128i Y, const u8 * in, return aesni_gcm_ghash_last (T, kd, d, 1, n_left); } -static_always_inline __m128i -aesni_gcm_dec (__m128i T, aes_gcm_key_data_t * kd, __m128i Y, const u8 * in, - const u8 * out, u32 n_left, int rounds) +static_always_inline u8x16 +aesni_gcm_dec (u8x16 T, aes_gcm_key_data_t * kd, u32x4 Y, u8x16u * inv, + u8x16u * outv, u32 n_left, int rounds) { - __m128i *inv = (__m128i *) in, *outv = (__m128i *) out; - __m128i d[8]; + u8x16 d[8]; u32 ctr = 1; while (n_left >= 128) @@ -572,12 +530,13 @@ aesni_gcm_dec (__m128i T, aes_gcm_key_data_t * kd, __m128i Y, const u8 * in, } static_always_inline int -aes_gcm (const u8 * in, u8 * out, const u8 * addt, const u8 * iv, u8 * tag, +aes_gcm (u8x16u * in, u8x16u * out, u8x16u * addt, u8x16u * iv, u8x16u * tag, u32 data_bytes, u32 aad_bytes, u8 tag_len, aes_gcm_key_data_t * kd, int aes_rounds, int is_encrypt) { int i; - __m128i r, Y0, T = { }; + u8x16 r, T = { }; + u32x4 Y0; ghash_data_t _gd, *gd = &_gd; _mm_prefetch (iv, _MM_HINT_T0); @@ -586,15 +545,15 @@ aes_gcm (const u8 * in, u8 * out, const u8 * addt, const u8 * iv, u8 * tag, /* calculate ghash for AAD - optimized for ipsec common cases */ if (aad_bytes == 8) - T = aesni_gcm_ghash (T, kd, (__m128i *) addt, 8); + T = aesni_gcm_ghash (T, kd, addt, 8); else if (aad_bytes == 12) - T = aesni_gcm_ghash (T, kd, (__m128i *) addt, 12); + T = aesni_gcm_ghash (T, kd, addt, 12); else - T = aesni_gcm_ghash (T, kd, (__m128i *) addt, aad_bytes); + T = aesni_gcm_ghash (T, kd, addt, aad_bytes); /* initalize counter */ - Y0 = CLIB_MEM_OVERFLOW_LOAD (_mm_loadu_si128, (__m128i *) iv); - Y0 = _mm_insert_epi32 (Y0, clib_host_to_net_u32 (1), 3); + Y0 = (u32x4) aes_load_partial (iv, 12); + Y0[3] = clib_host_to_net_u32 (1); /* ghash and encrypt/edcrypt */ if (is_encrypt) @@ -604,26 +563,24 @@ aes_gcm (const u8 * in, u8 * out, const u8 * addt, const u8 * iv, u8 * tag, _mm_prefetch (tag, _MM_HINT_T0); - /* Finalize ghash */ - r[0] = data_bytes; - r[1] = aad_bytes; - - /* bytes to bits */ - r <<= 3; + /* Finalize ghash - data bytes and aad bytes converted to bits */ + /* *INDENT-OFF* */ + r = (u8x16) ((u64x2) {data_bytes, aad_bytes} << 3); + /* *INDENT-ON* */ /* interleaved computation of final ghash and E(Y0, k) */ ghash_mul_first (gd, r ^ T, kd->Hi[0]); - r = kd->Ke[0] ^ Y0; + r = kd->Ke[0] ^ (u8x16) Y0; for (i = 1; i < 5; i += 1) - r = _mm_aesenc_si128 (r, kd->Ke[i]); + r = aes_enc_round (r, kd->Ke[i]); ghash_reduce (gd); ghash_reduce2 (gd); for (; i < 9; i += 1) - r = _mm_aesenc_si128 (r, kd->Ke[i]); + r = aes_enc_round (r, kd->Ke[i]); T = ghash_final (gd); for (; i < aes_rounds; i += 1) - r = _mm_aesenc_si128 (r, kd->Ke[i]); - r = _mm_aesenclast_si128 (r, kd->Ke[aes_rounds]); + r = aes_enc_round (r, kd->Ke[i]); + r = aes_enc_last_round (r, kd->Ke[aes_rounds]); T = aesni_gcm_bswap (T) ^ r; /* tag_len 16 -> 0 */ @@ -633,16 +590,15 @@ aes_gcm (const u8 * in, u8 * out, const u8 * addt, const u8 * iv, u8 * tag, { /* store tag */ if (tag_len) - aesni_gcm_store_partial ((__m128i *) tag, T, (1 << tag_len) - 1); + aes_store_partial (tag, T, (1 << tag_len) - 1); else - _mm_storeu_si128 ((__m128i *) tag, T); + tag[0] = T; } else { /* check tag */ u16 tag_mask = tag_len ? (1 << tag_len) - 1 : 0xffff; - r = _mm_loadu_si128 ((__m128i *) tag); - if (_mm_movemask_epi8 (r == T) != tag_mask) + if ((u8x16_msb_mask (tag[0] == T) & tag_mask) != tag_mask) return 0; } return 1; @@ -660,7 +616,8 @@ aesni_ops_enc_aes_gcm (vlib_main_t * vm, vnet_crypto_op_t * ops[], next: kd = (aes_gcm_key_data_t *) cm->key_data[op->key_index]; - aes_gcm (op->src, op->dst, op->aad, op->iv, op->tag, op->len, op->aad_len, + aes_gcm ((u8x16u *) op->src, (u8x16u *) op->dst, (u8x16u *) op->aad, + (u8x16u *) op->iv, (u8x16u *) op->tag, op->len, op->aad_len, op->tag_len, kd, AES_KEY_ROUNDS (ks), /* is_encrypt */ 1); op->status = VNET_CRYPTO_OP_STATUS_COMPLETED; @@ -685,7 +642,8 @@ aesni_ops_dec_aes_gcm (vlib_main_t * vm, vnet_crypto_op_t * ops[], next: kd = (aes_gcm_key_data_t *) cm->key_data[op->key_index]; - rv = aes_gcm (op->src, op->dst, op->aad, op->iv, op->tag, op->len, + rv = aes_gcm ((u8x16u *) op->src, (u8x16u *) op->dst, (u8x16u *) op->aad, + (u8x16u *) op->iv, (u8x16u *) op->tag, op->len, op->aad_len, op->tag_len, kd, AES_KEY_ROUNDS (ks), /* is_encrypt */ 0); @@ -712,8 +670,7 @@ static_always_inline void * aesni_gcm_key_exp (vnet_crypto_key_t * key, aes_key_size_t ks) { aes_gcm_key_data_t *kd; - __m128i H; - int i; + u8x16 H; kd = clib_mem_alloc_aligned (sizeof (*kd), CLIB_CACHE_LINE_BYTES); @@ -721,12 +678,9 @@ aesni_gcm_key_exp (vnet_crypto_key_t * key, aes_key_size_t ks) aes_key_expand ((u8x16 *) kd->Ke, key->data, ks); /* pre-calculate H */ - H = kd->Ke[0]; - for (i = 1; i < AES_KEY_ROUNDS (ks); i += 1) - H = _mm_aesenc_si128 (H, kd->Ke[i]); - H = _mm_aesenclast_si128 (H, kd->Ke[i]); + H = aes_encrypt_block (u8x16_splat (0), kd->Ke, ks); H = aesni_gcm_bswap (H); - ghash_precompute (H, (__m128i *) kd->Hi, 8); + ghash_precompute (H, (u8x16 *) kd->Hi, 8); return kd; } |