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-rw-r--r--src/vppinfra/crypto/aes_gcm.h975
1 files changed, 975 insertions, 0 deletions
diff --git a/src/vppinfra/crypto/aes_gcm.h b/src/vppinfra/crypto/aes_gcm.h
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+++ b/src/vppinfra/crypto/aes_gcm.h
@@ -0,0 +1,975 @@
+/* SPDX-License-Identifier: Apache-2.0
+ * Copyright(c) 2023 Cisco Systems, Inc.
+ */
+
+#ifndef __crypto_aes_gcm_h__
+#define __crypto_aes_gcm_h__
+
+#include <vppinfra/clib.h>
+#include <vppinfra/vector.h>
+#include <vppinfra/cache.h>
+#include <vppinfra/string.h>
+#include <vppinfra/crypto/aes.h>
+#include <vppinfra/crypto/ghash.h>
+
+#define NUM_HI 36
+#if defined(__VAES__) && defined(__AVX512F__)
+typedef u8x64 aes_data_t;
+typedef u8x64u aes_ghash_t;
+typedef u8x64u aes_mem_t;
+typedef u32x16 aes_gcm_counter_t;
+#define N 64
+#define aes_gcm_load_partial(p, n) u8x64_load_partial ((u8 *) (p), n)
+#define aes_gcm_store_partial(v, p, n) u8x64_store_partial (v, (u8 *) (p), n)
+#define aes_gcm_splat(v) u8x64_splat (v)
+#define aes_gcm_reflect(r) u8x64_reflect_u8x16 (r)
+#define aes_gcm_ghash_reduce(c) ghash4_reduce (&(c)->gd)
+#define aes_gcm_ghash_reduce2(c) ghash4_reduce2 (&(c)->gd)
+#define aes_gcm_ghash_final(c) (c)->T = ghash4_final (&(c)->gd)
+#elif defined(__VAES__)
+typedef u8x32 aes_data_t;
+typedef u8x32u aes_ghash_t;
+typedef u8x32u aes_mem_t;
+typedef u32x8 aes_gcm_counter_t;
+#define N 32
+#define aes_gcm_load_partial(p, n) u8x32_load_partial ((u8 *) (p), n)
+#define aes_gcm_store_partial(v, p, n) u8x32_store_partial (v, (u8 *) (p), n)
+#define aes_gcm_splat(v) u8x32_splat (v)
+#define aes_gcm_reflect(r) u8x32_reflect_u8x16 (r)
+#define aes_gcm_ghash_reduce(c) ghash2_reduce (&(c)->gd)
+#define aes_gcm_ghash_reduce2(c) ghash2_reduce2 (&(c)->gd)
+#define aes_gcm_ghash_final(c) (c)->T = ghash2_final (&(c)->gd)
+#else
+typedef u8x16 aes_data_t;
+typedef u8x16 aes_ghash_t;
+typedef u8x16u aes_mem_t;
+typedef u32x4 aes_gcm_counter_t;
+#define N 16
+#define aes_gcm_load_partial(p, n) u8x16_load_partial ((u8 *) (p), n)
+#define aes_gcm_store_partial(v, p, n) u8x16_store_partial (v, (u8 *) (p), n)
+#define aes_gcm_splat(v) u8x16_splat (v)
+#define aes_gcm_reflect(r) u8x16_reflect (r)
+#define aes_gcm_ghash_reduce(c) ghash_reduce (&(c)->gd)
+#define aes_gcm_ghash_reduce2(c) ghash_reduce2 (&(c)->gd)
+#define aes_gcm_ghash_final(c) (c)->T = ghash_final (&(c)->gd)
+#endif
+#define N_LANES (N / 16)
+
+typedef enum
+{
+ AES_GCM_OP_UNKNONW = 0,
+ AES_GCM_OP_ENCRYPT,
+ AES_GCM_OP_DECRYPT,
+ AES_GCM_OP_GMAC
+} aes_gcm_op_t;
+
+typedef union
+{
+ u8x16 x1;
+ u8x32 x2;
+ u8x64 x4;
+ u8x16 lanes[4];
+} __clib_aligned (64)
+aes_gcm_expaned_key_t;
+
+typedef struct
+{
+ /* pre-calculated hash key values */
+ const u8x16 Hi[NUM_HI];
+ /* extracted AES key */
+ const aes_gcm_expaned_key_t Ke[AES_KEY_ROUNDS (AES_KEY_256) + 1];
+} aes_gcm_key_data_t;
+
+typedef struct
+{
+ aes_gcm_op_t operation;
+ int last;
+ u8 rounds;
+ uword data_bytes;
+ uword aad_bytes;
+
+ u8x16 T;
+
+ /* hash */
+ const u8x16 *Hi;
+ const aes_ghash_t *next_Hi;
+
+ /* expaded keys */
+ const aes_gcm_expaned_key_t *Ke;
+
+ /* counter */
+ u32 counter;
+ u8x16 EY0;
+ aes_gcm_counter_t Y;
+
+ /* ghash */
+ ghash_data_t gd;
+} aes_gcm_ctx_t;
+
+static_always_inline void
+aes_gcm_ghash_mul_first (aes_gcm_ctx_t *ctx, aes_data_t data, u32 n_lanes)
+{
+ uword hash_offset = NUM_HI - n_lanes;
+ ctx->next_Hi = (aes_ghash_t *) (ctx->Hi + hash_offset);
+#if N_LANES == 4
+ u8x64 tag4 = {};
+ tag4 = u8x64_insert_u8x16 (tag4, ctx->T, 0);
+ ghash4_mul_first (&ctx->gd, aes_gcm_reflect (data) ^ tag4, *ctx->next_Hi++);
+#elif N_LANES == 2
+ u8x32 tag2 = {};
+ tag2 = u8x32_insert_lo (tag2, ctx->T);
+ ghash2_mul_first (&ctx->gd, aes_gcm_reflect (data) ^ tag2, *ctx->next_Hi++);
+#else
+ ghash_mul_first (&ctx->gd, aes_gcm_reflect (data) ^ ctx->T, *ctx->next_Hi++);
+#endif
+}
+
+static_always_inline void
+aes_gcm_ghash_mul_next (aes_gcm_ctx_t *ctx, aes_data_t data)
+{
+#if N_LANES == 4
+ ghash4_mul_next (&ctx->gd, aes_gcm_reflect (data), *ctx->next_Hi++);
+#elif N_LANES == 2
+ ghash2_mul_next (&ctx->gd, aes_gcm_reflect (data), *ctx->next_Hi++);
+#else
+ ghash_mul_next (&ctx->gd, aes_gcm_reflect (data), *ctx->next_Hi++);
+#endif
+}
+
+static_always_inline void
+aes_gcm_ghash_mul_bit_len (aes_gcm_ctx_t *ctx)
+{
+ u8x16 r = (u8x16) ((u64x2){ ctx->data_bytes, ctx->aad_bytes } << 3);
+#if N_LANES == 4
+ u8x64 h = u8x64_insert_u8x16 (u8x64_zero (), ctx->Hi[NUM_HI - 1], 0);
+ u8x64 r4 = u8x64_insert_u8x16 (u8x64_zero (), r, 0);
+ ghash4_mul_next (&ctx->gd, r4, h);
+#elif N_LANES == 2
+ u8x32 h = u8x32_insert_lo (u8x32_zero (), ctx->Hi[NUM_HI - 1]);
+ u8x32 r2 = u8x32_insert_lo (u8x32_zero (), r);
+ ghash2_mul_next (&ctx->gd, r2, h);
+#else
+ ghash_mul_next (&ctx->gd, r, ctx->Hi[NUM_HI - 1]);
+#endif
+}
+
+static_always_inline void
+aes_gcm_enc_ctr0_round (aes_gcm_ctx_t *ctx, int aes_round)
+{
+ if (aes_round == 0)
+ ctx->EY0 ^= ctx->Ke[0].x1;
+ else if (aes_round == ctx->rounds)
+ ctx->EY0 = aes_enc_last_round (ctx->EY0, ctx->Ke[aes_round].x1);
+ else
+ ctx->EY0 = aes_enc_round (ctx->EY0, ctx->Ke[aes_round].x1);
+}
+
+static_always_inline void
+aes_gcm_ghash (aes_gcm_ctx_t *ctx, u8 *data, u32 n_left)
+{
+ uword i;
+ aes_data_t r = {};
+ const aes_mem_t *d = (aes_mem_t *) data;
+
+ for (; n_left >= 8 * N; n_left -= 8 * N, d += 8)
+ {
+ if (ctx->operation == AES_GCM_OP_GMAC && n_left == N * 8)
+ {
+ aes_gcm_ghash_mul_first (ctx, d[0], 8 * N_LANES + 1);
+ for (i = 1; i < 8; i++)
+ aes_gcm_ghash_mul_next (ctx, d[i]);
+ aes_gcm_ghash_mul_bit_len (ctx);
+ aes_gcm_ghash_reduce (ctx);
+ aes_gcm_ghash_reduce2 (ctx);
+ aes_gcm_ghash_final (ctx);
+ goto done;
+ }
+
+ aes_gcm_ghash_mul_first (ctx, d[0], 8 * N_LANES);
+ for (i = 1; i < 8; i++)
+ aes_gcm_ghash_mul_next (ctx, d[i]);
+ aes_gcm_ghash_reduce (ctx);
+ aes_gcm_ghash_reduce2 (ctx);
+ aes_gcm_ghash_final (ctx);
+ }
+
+ if (n_left > 0)
+ {
+ int n_lanes = (n_left + 15) / 16;
+
+ if (ctx->operation == AES_GCM_OP_GMAC)
+ n_lanes++;
+
+ if (n_left < N)
+ {
+ clib_memcpy_fast (&r, d, n_left);
+ aes_gcm_ghash_mul_first (ctx, r, n_lanes);
+ }
+ else
+ {
+ aes_gcm_ghash_mul_first (ctx, d[0], n_lanes);
+ n_left -= N;
+ i = 1;
+
+ if (n_left >= 4 * N)
+ {
+ aes_gcm_ghash_mul_next (ctx, d[i]);
+ aes_gcm_ghash_mul_next (ctx, d[i + 1]);
+ aes_gcm_ghash_mul_next (ctx, d[i + 2]);
+ aes_gcm_ghash_mul_next (ctx, d[i + 3]);
+ n_left -= 4 * N;
+ i += 4;
+ }
+ if (n_left >= 2 * N)
+ {
+ aes_gcm_ghash_mul_next (ctx, d[i]);
+ aes_gcm_ghash_mul_next (ctx, d[i + 1]);
+ n_left -= 2 * N;
+ i += 2;
+ }
+
+ if (n_left >= N)
+ {
+ aes_gcm_ghash_mul_next (ctx, d[i]);
+ n_left -= N;
+ i += 1;
+ }
+
+ if (n_left)
+ {
+ clib_memcpy_fast (&r, d + i, n_left);
+ aes_gcm_ghash_mul_next (ctx, r);
+ }
+ }
+
+ if (ctx->operation == AES_GCM_OP_GMAC)
+ aes_gcm_ghash_mul_bit_len (ctx);
+ aes_gcm_ghash_reduce (ctx);
+ aes_gcm_ghash_reduce2 (ctx);
+ aes_gcm_ghash_final (ctx);
+ }
+ else if (ctx->operation == AES_GCM_OP_GMAC)
+ {
+ u8x16 r = (u8x16) ((u64x2){ ctx->data_bytes, ctx->aad_bytes } << 3);
+ ctx->T = ghash_mul (r ^ ctx->T, ctx->Hi[NUM_HI - 1]);
+ }
+
+done:
+ /* encrypt counter 0 E(Y0, k) */
+ if (ctx->operation == AES_GCM_OP_GMAC)
+ for (int i = 0; i < ctx->rounds + 1; i += 1)
+ aes_gcm_enc_ctr0_round (ctx, i);
+}
+
+static_always_inline void
+aes_gcm_enc_first_round (aes_gcm_ctx_t *ctx, aes_data_t *r, uword n_blocks)
+{
+ const aes_gcm_expaned_key_t Ke0 = ctx->Ke[0];
+ uword i = 0;
+
+#if N_LANES == 4
+ const u32x16 ctr_inv_4444 = { 0, 0, 0, 4 << 24, 0, 0, 0, 4 << 24,
+ 0, 0, 0, 4 << 24, 0, 0, 0, 4 << 24 };
+
+ const u32x16 ctr_4444 = {
+ 4, 0, 0, 0, 4, 0, 0, 0, 4, 0, 0, 0, 4, 0, 0, 0,
+ };
+
+ /* As counter is stored in network byte order for performance reasons we
+ are incrementing least significant byte only except in case where we
+ overlow. As we are processing four 512-blocks in parallel except the
+ last round, overflow can happen only when n == 4 */
+
+ if (n_blocks == 4)
+ for (; i < 2; i++)
+ {
+ r[i] = Ke0.x4 ^ (u8x64) ctx->Y;
+ ctx->Y += ctr_inv_4444;
+ }
+
+ if (n_blocks == 4 && PREDICT_FALSE ((u8) ctx->counter == 242))
+ {
+ u32x16 Yr = (u32x16) aes_gcm_reflect ((u8x64) ctx->Y);
+
+ for (; i < n_blocks; i++)
+ {
+ r[i] = Ke0.x4 ^ (u8x64) ctx->Y;
+ Yr += ctr_4444;
+ ctx->Y = (u32x16) aes_gcm_reflect ((u8x64) Yr);
+ }
+ }
+ else
+ {
+ for (; i < n_blocks; i++)
+ {
+ r[i] = Ke0.x4 ^ (u8x64) ctx->Y;
+ ctx->Y += ctr_inv_4444;
+ }
+ }
+ ctx->counter += n_blocks * 4;
+#elif N_LANES == 2
+ const u32x8 ctr_inv_22 = { 0, 0, 0, 2 << 24, 0, 0, 0, 2 << 24 };
+ const u32x8 ctr_22 = { 2, 0, 0, 0, 2, 0, 0, 0 };
+
+ /* As counter is stored in network byte order for performance reasons we
+ are incrementing least significant byte only except in case where we
+ overlow. As we are processing four 512-blocks in parallel except the
+ last round, overflow can happen only when n == 4 */
+
+ if (n_blocks == 4)
+ for (; i < 2; i++)
+ {
+ r[i] = Ke0.x2 ^ (u8x32) ctx->Y;
+ ctx->Y += ctr_inv_22;
+ }
+
+ if (n_blocks == 4 && PREDICT_FALSE ((u8) ctx->counter == 250))
+ {
+ u32x8 Yr = (u32x8) aes_gcm_reflect ((u8x32) ctx->Y);
+
+ for (; i < n_blocks; i++)
+ {
+ r[i] = Ke0.x2 ^ (u8x32) ctx->Y;
+ Yr += ctr_22;
+ ctx->Y = (u32x8) aes_gcm_reflect ((u8x32) Yr);
+ }
+ }
+ else
+ {
+ for (; i < n_blocks; i++)
+ {
+ r[i] = Ke0.x2 ^ (u8x32) ctx->Y;
+ ctx->Y += ctr_inv_22;
+ }
+ }
+ ctx->counter += n_blocks * 2;
+#else
+ const u32x4 ctr_inv_1 = { 0, 0, 0, 1 << 24 };
+
+ if (PREDICT_TRUE ((u8) ctx->counter < 0xfe) || n_blocks < 3)
+ {
+ for (; i < n_blocks; i++)
+ {
+ r[i] = Ke0.x1 ^ (u8x16) ctx->Y;
+ ctx->Y += ctr_inv_1;
+ }
+ ctx->counter += n_blocks;
+ }
+ else
+ {
+ r[i++] = Ke0.x1 ^ (u8x16) ctx->Y;
+ ctx->Y += ctr_inv_1;
+ ctx->counter += 1;
+
+ for (; i < n_blocks; i++)
+ {
+ r[i] = Ke0.x1 ^ (u8x16) ctx->Y;
+ ctx->counter++;
+ ctx->Y[3] = clib_host_to_net_u32 (ctx->counter);
+ }
+ }
+#endif
+}
+
+static_always_inline void
+aes_gcm_enc_round (aes_data_t *r, const aes_gcm_expaned_key_t *Ke,
+ uword n_blocks)
+{
+ for (int i = 0; i < n_blocks; i++)
+#if N_LANES == 4
+ r[i] = aes_enc_round_x4 (r[i], Ke->x4);
+#elif N_LANES == 2
+ r[i] = aes_enc_round_x2 (r[i], Ke->x2);
+#else
+ r[i] = aes_enc_round (r[i], Ke->x1);
+#endif
+}
+
+static_always_inline void
+aes_gcm_enc_last_round (aes_gcm_ctx_t *ctx, aes_data_t *r, aes_data_t *d,
+ const aes_gcm_expaned_key_t *Ke, uword n_blocks)
+{
+ /* additional ronuds for AES-192 and AES-256 */
+ for (int i = 10; i < ctx->rounds; i++)
+ aes_gcm_enc_round (r, Ke + i, n_blocks);
+
+ for (int i = 0; i < n_blocks; i++)
+#if N_LANES == 4
+ d[i] ^= aes_enc_last_round_x4 (r[i], Ke[ctx->rounds].x4);
+#elif N_LANES == 2
+ d[i] ^= aes_enc_last_round_x2 (r[i], Ke[ctx->rounds].x2);
+#else
+ d[i] ^= aes_enc_last_round (r[i], Ke[ctx->rounds].x1);
+#endif
+}
+
+static_always_inline void
+aes_gcm_calc (aes_gcm_ctx_t *ctx, aes_data_t *d, const u8 *src, u8 *dst, u32 n,
+ u32 n_bytes, int with_ghash)
+{
+ const aes_gcm_expaned_key_t *k = ctx->Ke;
+ const aes_mem_t *sv = (aes_mem_t *) src;
+ aes_mem_t *dv = (aes_mem_t *) dst;
+ uword ghash_blocks, gc = 1;
+ aes_data_t r[4];
+ u32 i, n_lanes;
+
+ if (ctx->operation == AES_GCM_OP_ENCRYPT)
+ {
+ ghash_blocks = 4;
+ n_lanes = N_LANES * 4;
+ }
+ else
+ {
+ ghash_blocks = n;
+ n_lanes = n * N_LANES;
+#if N_LANES != 1
+ if (ctx->last)
+ n_lanes = (n_bytes + 15) / 16;
+#endif
+ }
+
+ n_bytes -= (n - 1) * N;
+
+ /* AES rounds 0 and 1 */
+ aes_gcm_enc_first_round (ctx, r, n);
+ aes_gcm_enc_round (r, k + 1, n);
+
+ /* load data - decrypt round */
+ if (ctx->operation == AES_GCM_OP_DECRYPT)
+ {
+ for (i = 0; i < n - ctx->last; i++)
+ d[i] = sv[i];
+
+ if (ctx->last)
+ d[n - 1] = aes_gcm_load_partial ((u8 *) (sv + n - 1), n_bytes);
+ }
+
+ /* GHASH multiply block 0 */
+ if (with_ghash)
+ aes_gcm_ghash_mul_first (ctx, d[0], n_lanes);
+
+ /* AES rounds 2 and 3 */
+ aes_gcm_enc_round (r, k + 2, n);
+ aes_gcm_enc_round (r, k + 3, n);
+
+ /* GHASH multiply block 1 */
+ if (with_ghash && gc++ < ghash_blocks)
+ aes_gcm_ghash_mul_next (ctx, (d[1]));
+
+ /* AES rounds 4 and 5 */
+ aes_gcm_enc_round (r, k + 4, n);
+ aes_gcm_enc_round (r, k + 5, n);
+
+ /* GHASH multiply block 2 */
+ if (with_ghash && gc++ < ghash_blocks)
+ aes_gcm_ghash_mul_next (ctx, (d[2]));
+
+ /* AES rounds 6 and 7 */
+ aes_gcm_enc_round (r, k + 6, n);
+ aes_gcm_enc_round (r, k + 7, n);
+
+ /* GHASH multiply block 3 */
+ if (with_ghash && gc++ < ghash_blocks)
+ aes_gcm_ghash_mul_next (ctx, (d[3]));
+
+ /* load 4 blocks of data - decrypt round */
+ if (ctx->operation == AES_GCM_OP_ENCRYPT)
+ {
+ for (i = 0; i < n - ctx->last; i++)
+ d[i] = sv[i];
+
+ if (ctx->last)
+ d[n - 1] = aes_gcm_load_partial (sv + n - 1, n_bytes);
+ }
+
+ /* AES rounds 8 and 9 */
+ aes_gcm_enc_round (r, k + 8, n);
+ aes_gcm_enc_round (r, k + 9, n);
+
+ /* AES last round(s) */
+ aes_gcm_enc_last_round (ctx, r, d, k, n);
+
+ /* store data */
+ for (i = 0; i < n - ctx->last; i++)
+ dv[i] = d[i];
+
+ if (ctx->last)
+ aes_gcm_store_partial (d[n - 1], dv + n - 1, n_bytes);
+
+ /* GHASH reduce 1st step */
+ aes_gcm_ghash_reduce (ctx);
+
+ /* GHASH reduce 2nd step */
+ if (with_ghash)
+ aes_gcm_ghash_reduce2 (ctx);
+
+ /* GHASH final step */
+ if (with_ghash)
+ aes_gcm_ghash_final (ctx);
+}
+
+static_always_inline void
+aes_gcm_calc_double (aes_gcm_ctx_t *ctx, aes_data_t *d, const u8 *src, u8 *dst,
+ int with_ghash)
+{
+ const aes_gcm_expaned_key_t *k = ctx->Ke;
+ const aes_mem_t *sv = (aes_mem_t *) src;
+ aes_mem_t *dv = (aes_mem_t *) dst;
+ aes_data_t r[4];
+
+ /* AES rounds 0 and 1 */
+ aes_gcm_enc_first_round (ctx, r, 4);
+ aes_gcm_enc_round (r, k + 1, 4);
+
+ /* load 4 blocks of data - decrypt round */
+ if (ctx->operation == AES_GCM_OP_DECRYPT)
+ for (int i = 0; i < 4; i++)
+ d[i] = sv[i];
+
+ /* GHASH multiply block 0 */
+ aes_gcm_ghash_mul_first (ctx, d[0], N_LANES * 8);
+
+ /* AES rounds 2 and 3 */
+ aes_gcm_enc_round (r, k + 2, 4);
+ aes_gcm_enc_round (r, k + 3, 4);
+
+ /* GHASH multiply block 1 */
+ aes_gcm_ghash_mul_next (ctx, (d[1]));
+
+ /* AES rounds 4 and 5 */
+ aes_gcm_enc_round (r, k + 4, 4);
+ aes_gcm_enc_round (r, k + 5, 4);
+
+ /* GHASH multiply block 2 */
+ aes_gcm_ghash_mul_next (ctx, (d[2]));
+
+ /* AES rounds 6 and 7 */
+ aes_gcm_enc_round (r, k + 6, 4);
+ aes_gcm_enc_round (r, k + 7, 4);
+
+ /* GHASH multiply block 3 */
+ aes_gcm_ghash_mul_next (ctx, (d[3]));
+
+ /* AES rounds 8 and 9 */
+ aes_gcm_enc_round (r, k + 8, 4);
+ aes_gcm_enc_round (r, k + 9, 4);
+
+ /* load 4 blocks of data - encrypt round */
+ if (ctx->operation == AES_GCM_OP_ENCRYPT)
+ for (int i = 0; i < 4; i++)
+ d[i] = sv[i];
+
+ /* AES last round(s) */
+ aes_gcm_enc_last_round (ctx, r, d, k, 4);
+
+ /* store 4 blocks of data */
+ for (int i = 0; i < 4; i++)
+ dv[i] = d[i];
+
+ /* load next 4 blocks of data data - decrypt round */
+ if (ctx->operation == AES_GCM_OP_DECRYPT)
+ for (int i = 0; i < 4; i++)
+ d[i] = sv[i + 4];
+
+ /* GHASH multiply block 4 */
+ aes_gcm_ghash_mul_next (ctx, (d[0]));
+
+ /* AES rounds 0 and 1 */
+ aes_gcm_enc_first_round (ctx, r, 4);
+ aes_gcm_enc_round (r, k + 1, 4);
+
+ /* GHASH multiply block 5 */
+ aes_gcm_ghash_mul_next (ctx, (d[1]));
+
+ /* AES rounds 2 and 3 */
+ aes_gcm_enc_round (r, k + 2, 4);
+ aes_gcm_enc_round (r, k + 3, 4);
+
+ /* GHASH multiply block 6 */
+ aes_gcm_ghash_mul_next (ctx, (d[2]));
+
+ /* AES rounds 4 and 5 */
+ aes_gcm_enc_round (r, k + 4, 4);
+ aes_gcm_enc_round (r, k + 5, 4);
+
+ /* GHASH multiply block 7 */
+ aes_gcm_ghash_mul_next (ctx, (d[3]));
+
+ /* AES rounds 6 and 7 */
+ aes_gcm_enc_round (r, k + 6, 4);
+ aes_gcm_enc_round (r, k + 7, 4);
+
+ /* GHASH reduce 1st step */
+ aes_gcm_ghash_reduce (ctx);
+
+ /* AES rounds 8 and 9 */
+ aes_gcm_enc_round (r, k + 8, 4);
+ aes_gcm_enc_round (r, k + 9, 4);
+
+ /* GHASH reduce 2nd step */
+ aes_gcm_ghash_reduce2 (ctx);
+
+ /* load 4 blocks of data - encrypt round */
+ if (ctx->operation == AES_GCM_OP_ENCRYPT)
+ for (int i = 0; i < 4; i++)
+ d[i] = sv[i + 4];
+
+ /* AES last round(s) */
+ aes_gcm_enc_last_round (ctx, r, d, k, 4);
+
+ /* store data */
+ for (int i = 0; i < 4; i++)
+ dv[i + 4] = d[i];
+
+ /* GHASH final step */
+ aes_gcm_ghash_final (ctx);
+}
+
+static_always_inline void
+aes_gcm_mask_bytes (aes_data_t *d, uword n_bytes)
+{
+ const union
+ {
+ u8 b[64];
+ aes_data_t r;
+ } scale = {
+ .b = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15,
+ 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
+ 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47,
+ 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63 },
+ };
+
+ d[0] &= (aes_gcm_splat (n_bytes) > scale.r);
+}
+
+static_always_inline void
+aes_gcm_calc_last (aes_gcm_ctx_t *ctx, aes_data_t *d, int n_blocks,
+ u32 n_bytes)
+{
+ int n_lanes = (N_LANES == 1 ? n_blocks : (n_bytes + 15) / 16) + 1;
+ n_bytes -= (n_blocks - 1) * N;
+ int i;
+
+ aes_gcm_enc_ctr0_round (ctx, 0);
+ aes_gcm_enc_ctr0_round (ctx, 1);
+
+ if (n_bytes != N)
+ aes_gcm_mask_bytes (d + n_blocks - 1, n_bytes);
+
+ aes_gcm_ghash_mul_first (ctx, d[0], n_lanes);
+
+ aes_gcm_enc_ctr0_round (ctx, 2);
+ aes_gcm_enc_ctr0_round (ctx, 3);
+
+ if (n_blocks > 1)
+ aes_gcm_ghash_mul_next (ctx, d[1]);
+
+ aes_gcm_enc_ctr0_round (ctx, 4);
+ aes_gcm_enc_ctr0_round (ctx, 5);
+
+ if (n_blocks > 2)
+ aes_gcm_ghash_mul_next (ctx, d[2]);
+
+ aes_gcm_enc_ctr0_round (ctx, 6);
+ aes_gcm_enc_ctr0_round (ctx, 7);
+
+ if (n_blocks > 3)
+ aes_gcm_ghash_mul_next (ctx, d[3]);
+
+ aes_gcm_enc_ctr0_round (ctx, 8);
+ aes_gcm_enc_ctr0_round (ctx, 9);
+
+ aes_gcm_ghash_mul_bit_len (ctx);
+ aes_gcm_ghash_reduce (ctx);
+
+ for (i = 10; i < ctx->rounds; i++)
+ aes_gcm_enc_ctr0_round (ctx, i);
+
+ aes_gcm_ghash_reduce2 (ctx);
+
+ aes_gcm_ghash_final (ctx);
+
+ aes_gcm_enc_ctr0_round (ctx, i);
+}
+
+static_always_inline void
+aes_gcm_enc (aes_gcm_ctx_t *ctx, const u8 *src, u8 *dst, u32 n_left)
+{
+ aes_data_t d[4];
+
+ if (PREDICT_FALSE (n_left == 0))
+ {
+ int i;
+ for (i = 0; i < ctx->rounds + 1; i++)
+ aes_gcm_enc_ctr0_round (ctx, i);
+ return;
+ }
+
+ if (n_left < 4 * N)
+ {
+ ctx->last = 1;
+ if (n_left > 3 * N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 4, n_left, /* with_ghash */ 0);
+ aes_gcm_calc_last (ctx, d, 4, n_left);
+ }
+ else if (n_left > 2 * N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 3, n_left, /* with_ghash */ 0);
+ aes_gcm_calc_last (ctx, d, 3, n_left);
+ }
+ else if (n_left > N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 2, n_left, /* with_ghash */ 0);
+ aes_gcm_calc_last (ctx, d, 2, n_left);
+ }
+ else
+ {
+ aes_gcm_calc (ctx, d, src, dst, 1, n_left, /* with_ghash */ 0);
+ aes_gcm_calc_last (ctx, d, 1, n_left);
+ }
+ return;
+ }
+ aes_gcm_calc (ctx, d, src, dst, 4, 4 * N, /* with_ghash */ 0);
+
+ /* next */
+ n_left -= 4 * N;
+ dst += 4 * N;
+ src += 4 * N;
+
+ for (; n_left >= 8 * N; n_left -= 8 * N, src += 8 * N, dst += 8 * N)
+ aes_gcm_calc_double (ctx, d, src, dst, /* with_ghash */ 1);
+
+ if (n_left >= 4 * N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 4, 4 * N, /* with_ghash */ 1);
+
+ /* next */
+ n_left -= 4 * N;
+ dst += 4 * N;
+ src += 4 * N;
+ }
+
+ if (n_left == 0)
+ {
+ aes_gcm_calc_last (ctx, d, 4, 4 * N);
+ return;
+ }
+
+ ctx->last = 1;
+
+ if (n_left > 3 * N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 4, n_left, /* with_ghash */ 1);
+ aes_gcm_calc_last (ctx, d, 4, n_left);
+ }
+ else if (n_left > 2 * N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 3, n_left, /* with_ghash */ 1);
+ aes_gcm_calc_last (ctx, d, 3, n_left);
+ }
+ else if (n_left > N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 2, n_left, /* with_ghash */ 1);
+ aes_gcm_calc_last (ctx, d, 2, n_left);
+ }
+ else
+ {
+ aes_gcm_calc (ctx, d, src, dst, 1, n_left, /* with_ghash */ 1);
+ aes_gcm_calc_last (ctx, d, 1, n_left);
+ }
+}
+
+static_always_inline void
+aes_gcm_dec (aes_gcm_ctx_t *ctx, const u8 *src, u8 *dst, uword n_left)
+{
+ aes_data_t d[4] = {};
+ for (; n_left >= 8 * N; n_left -= 8 * N, dst += 8 * N, src += 8 * N)
+ aes_gcm_calc_double (ctx, d, src, dst, /* with_ghash */ 1);
+
+ if (n_left >= 4 * N)
+ {
+ aes_gcm_calc (ctx, d, src, dst, 4, 4 * N, /* with_ghash */ 1);
+
+ /* next */
+ n_left -= 4 * N;
+ dst += N * 4;
+ src += N * 4;
+ }
+
+ if (n_left == 0)
+ goto done;
+
+ ctx->last = 1;
+
+ if (n_left > 3 * N)
+ aes_gcm_calc (ctx, d, src, dst, 4, n_left, /* with_ghash */ 1);
+ else if (n_left > 2 * N)
+ aes_gcm_calc (ctx, d, src, dst, 3, n_left, /* with_ghash */ 1);
+ else if (n_left > N)
+ aes_gcm_calc (ctx, d, src, dst, 2, n_left, /* with_ghash */ 1);
+ else
+ aes_gcm_calc (ctx, d, src, dst, 1, n_left, /* with_ghash */ 1);
+
+ u8x16 r;
+done:
+ r = (u8x16) ((u64x2){ ctx->data_bytes, ctx->aad_bytes } << 3);
+ ctx->T = ghash_mul (r ^ ctx->T, ctx->Hi[NUM_HI - 1]);
+
+ /* encrypt counter 0 E(Y0, k) */
+ for (int i = 0; i < ctx->rounds + 1; i += 1)
+ aes_gcm_enc_ctr0_round (ctx, i);
+}
+
+static_always_inline int
+aes_gcm (const u8 *src, u8 *dst, const u8 *aad, u8 *ivp, u8 *tag,
+ u32 data_bytes, u32 aad_bytes, u8 tag_len,
+ const aes_gcm_key_data_t *kd, int aes_rounds, aes_gcm_op_t op)
+{
+ u8 *addt = (u8 *) aad;
+ u32x4 Y0;
+
+ aes_gcm_ctx_t _ctx = { .counter = 2,
+ .rounds = aes_rounds,
+ .operation = op,
+ .data_bytes = data_bytes,
+ .aad_bytes = aad_bytes,
+ .Hi = kd->Hi },
+ *ctx = &_ctx;
+
+ /* initalize counter */
+ Y0 = (u32x4) (u64x2){ *(u64u *) ivp, 0 };
+ Y0[2] = *(u32u *) (ivp + 8);
+ Y0[3] = 1 << 24;
+ ctx->EY0 = (u8x16) Y0;
+ ctx->Ke = kd->Ke;
+#if N_LANES == 4
+ ctx->Y = u32x16_splat_u32x4 (Y0) + (u32x16){
+ 0, 0, 0, 1 << 24, 0, 0, 0, 2 << 24, 0, 0, 0, 3 << 24, 0, 0, 0, 4 << 24,
+ };
+#elif N_LANES == 2
+ ctx->Y =
+ u32x8_splat_u32x4 (Y0) + (u32x8){ 0, 0, 0, 1 << 24, 0, 0, 0, 2 << 24 };
+#else
+ ctx->Y = Y0 + (u32x4){ 0, 0, 0, 1 << 24 };
+#endif
+
+ /* calculate ghash for AAD */
+ aes_gcm_ghash (ctx, addt, aad_bytes);
+
+ clib_prefetch_load (tag);
+
+ /* ghash and encrypt/edcrypt */
+ if (op == AES_GCM_OP_ENCRYPT)
+ aes_gcm_enc (ctx, src, dst, data_bytes);
+ else if (op == AES_GCM_OP_DECRYPT)
+ aes_gcm_dec (ctx, src, dst, data_bytes);
+
+ /* final tag is */
+ ctx->T = u8x16_reflect (ctx->T) ^ ctx->EY0;
+
+ /* tag_len 16 -> 0 */
+ tag_len &= 0xf;
+
+ if (op == AES_GCM_OP_ENCRYPT || op == AES_GCM_OP_GMAC)
+ {
+ /* store tag */
+ if (tag_len)
+ u8x16_store_partial (ctx->T, tag, tag_len);
+ else
+ ((u8x16u *) tag)[0] = ctx->T;
+ }
+ else
+ {
+ /* check tag */
+ if (tag_len)
+ {
+ u16 mask = pow2_mask (tag_len);
+ u8x16 expected = u8x16_load_partial (tag, tag_len);
+ if ((u8x16_msb_mask (expected == ctx->T) & mask) == mask)
+ return 1;
+ }
+ else
+ {
+ if (u8x16_is_equal (ctx->T, *(u8x16u *) tag))
+ return 1;
+ }
+ }
+ return 0;
+}
+
+static_always_inline void
+clib_aes_gcm_key_expand (aes_gcm_key_data_t *kd, const u8 *key,
+ aes_key_size_t ks)
+{
+ u8x16 H;
+ u8x16 ek[AES_KEY_ROUNDS (AES_KEY_256) + 1];
+ aes_gcm_expaned_key_t *Ke = (aes_gcm_expaned_key_t *) kd->Ke;
+
+ /* expand AES key */
+ aes_key_expand (ek, key, ks);
+ for (int i = 0; i < AES_KEY_ROUNDS (ks) + 1; i++)
+ Ke[i].lanes[0] = Ke[i].lanes[1] = Ke[i].lanes[2] = Ke[i].lanes[3] = ek[i];
+
+ /* pre-calculate H */
+ H = aes_encrypt_block (u8x16_zero (), ek, ks);
+ H = u8x16_reflect (H);
+ ghash_precompute (H, (u8x16 *) kd->Hi, ARRAY_LEN (kd->Hi));
+}
+
+static_always_inline void
+clib_aes128_gcm_enc (const aes_gcm_key_data_t *kd, const u8 *plaintext,
+ u32 data_bytes, const u8 *aad, u32 aad_bytes,
+ const u8 *iv, u32 tag_bytes, u8 *cyphertext, u8 *tag)
+{
+ aes_gcm (plaintext, cyphertext, aad, (u8 *) iv, tag, data_bytes, aad_bytes,
+ tag_bytes, kd, AES_KEY_ROUNDS (AES_KEY_128), AES_GCM_OP_ENCRYPT);
+}
+
+static_always_inline void
+clib_aes256_gcm_enc (const aes_gcm_key_data_t *kd, const u8 *plaintext,
+ u32 data_bytes, const u8 *aad, u32 aad_bytes,
+ const u8 *iv, u32 tag_bytes, u8 *cyphertext, u8 *tag)
+{
+ aes_gcm (plaintext, cyphertext, aad, (u8 *) iv, tag, data_bytes, aad_bytes,
+ tag_bytes, kd, AES_KEY_ROUNDS (AES_KEY_256), AES_GCM_OP_ENCRYPT);
+}
+
+static_always_inline int
+clib_aes128_gcm_dec (const aes_gcm_key_data_t *kd, const u8 *cyphertext,
+ u32 data_bytes, const u8 *aad, u32 aad_bytes,
+ const u8 *iv, const u8 *tag, u32 tag_bytes, u8 *plaintext)
+{
+ return aes_gcm (cyphertext, plaintext, aad, (u8 *) iv, (u8 *) tag,
+ data_bytes, aad_bytes, tag_bytes, kd,
+ AES_KEY_ROUNDS (AES_KEY_128), AES_GCM_OP_DECRYPT);
+}
+
+static_always_inline int
+clib_aes256_gcm_dec (const aes_gcm_key_data_t *kd, const u8 *cyphertext,
+ u32 data_bytes, const u8 *aad, u32 aad_bytes,
+ const u8 *iv, const u8 *tag, u32 tag_bytes, u8 *plaintext)
+{
+ return aes_gcm (cyphertext, plaintext, aad, (u8 *) iv, (u8 *) tag,
+ data_bytes, aad_bytes, tag_bytes, kd,
+ AES_KEY_ROUNDS (AES_KEY_256), AES_GCM_OP_DECRYPT);
+}
+
+static_always_inline void
+clib_aes128_gmac (const aes_gcm_key_data_t *kd, const u8 *data, u32 data_bytes,
+ const u8 *iv, u32 tag_bytes, u8 *tag)
+{
+ aes_gcm (0, 0, data, (u8 *) iv, tag, 0, data_bytes, tag_bytes, kd,
+ AES_KEY_ROUNDS (AES_KEY_128), AES_GCM_OP_GMAC);
+}
+
+static_always_inline void
+clib_aes256_gmac (const aes_gcm_key_data_t *kd, const u8 *data, u32 data_bytes,
+ const u8 *iv, u32 tag_bytes, u8 *tag)
+{
+ aes_gcm (0, 0, data, (u8 *) iv, tag, 0, data_bytes, tag_bytes, kd,
+ AES_KEY_ROUNDS (AES_KEY_256), AES_GCM_OP_GMAC);
+}
+
+#endif /* __crypto_aes_gcm_h__ */