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/*
*------------------------------------------------------------------
* Copyright (c) 2019 - 2021 Intel and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*------------------------------------------------------------------
*/
#ifndef included_cryptodev_h
#define included_cryptodev_h
#include <vnet/crypto/crypto.h>
#undef always_inline
#include <rte_cryptodev.h>
#define CRYPTODEV_NB_CRYPTO_OPS 1024
#define CRYPTODEV_CACHE_QUEUE_SIZE VNET_CRYPTO_FRAME_POOL_SIZE
#define CRYPTODEV_CACHE_QUEUE_MASK (VNET_CRYPTO_FRAME_POOL_SIZE - 1)
#define CRYPTODEV_MAX_INFLIGHT (CRYPTODEV_NB_CRYPTO_OPS - 1)
#define CRYPTODEV_AAD_MASK (CRYPTODEV_NB_CRYPTO_OPS - 1)
#define CRYPTODE_ENQ_MAX 64
#define CRYPTODE_DEQ_MAX 64
#define CRYPTODEV_NB_SESSION 4096
#define CRYPTODEV_MAX_IV_SIZE 16
#define CRYPTODEV_MAX_AAD_SIZE 16
#define CRYPTODEV_MAX_N_SGL 8 /**< maximum number of segments */
#define CRYPTODEV_MAX_PROCESED_IN_CACHE_QUEUE 8
#define CRYPTODEV_IV_OFFSET (offsetof (cryptodev_op_t, iv))
#define CRYPTODEV_AAD_OFFSET (offsetof (cryptodev_op_t, aad))
/* VNET_CRYPTO_ALGO, TYPE, DPDK_CRYPTO_ALGO, IV_LEN, TAG_LEN, AAD_LEN, KEY_LEN
*/
#define foreach_vnet_aead_crypto_conversion \
_ (AES_128_GCM, AEAD, AES_GCM, 12, 16, 8, 16) \
_ (AES_128_GCM, AEAD, AES_GCM, 12, 16, 12, 16) \
_ (AES_192_GCM, AEAD, AES_GCM, 12, 16, 8, 24) \
_ (AES_192_GCM, AEAD, AES_GCM, 12, 16, 12, 24) \
_ (AES_256_GCM, AEAD, AES_GCM, 12, 16, 8, 32) \
_ (AES_256_GCM, AEAD, AES_GCM, 12, 16, 12, 32) \
_ (CHACHA20_POLY1305, AEAD, CHACHA20_POLY1305, 12, 16, 0, 32) \
_ (CHACHA20_POLY1305, AEAD, CHACHA20_POLY1305, 12, 16, 8, 32) \
_ (CHACHA20_POLY1305, AEAD, CHACHA20_POLY1305, 12, 16, 12, 32)
/**
* crypto (alg, cryptodev_alg, key_size), hash (alg, digest-size)
**/
#define foreach_cryptodev_link_async_alg \
_ (AES_128_CBC, AES_CBC, 16, MD5, 12) \
_ (AES_192_CBC, AES_CBC, 24, MD5, 12) \
_ (AES_256_CBC, AES_CBC, 32, MD5, 12) \
_ (AES_128_CBC, AES_CBC, 16, SHA1, 12) \
_ (AES_192_CBC, AES_CBC, 24, SHA1, 12) \
_ (AES_256_CBC, AES_CBC, 32, SHA1, 12) \
_ (AES_128_CBC, AES_CBC, 16, SHA224, 14) \
_ (AES_192_CBC, AES_CBC, 24, SHA224, 14) \
_ (AES_256_CBC, AES_CBC, 32, SHA224, 14) \
_ (AES_128_CBC, AES_CBC, 16, SHA256, 16) \
_ (AES_192_CBC, AES_CBC, 24, SHA256, 16) \
_ (AES_256_CBC, AES_CBC, 32, SHA256, 16) \
_ (AES_128_CBC, AES_CBC, 16, SHA384, 24) \
_ (AES_192_CBC, AES_CBC, 24, SHA384, 24) \
_ (AES_256_CBC, AES_CBC, 32, SHA384, 24) \
_ (AES_128_CBC, AES_CBC, 16, SHA512, 32) \
_ (AES_192_CBC, AES_CBC, 24, SHA512, 32) \
_ (AES_256_CBC, AES_CBC, 32, SHA512, 32) \
_ (AES_128_CTR, AES_CTR, 16, SHA1, 12) \
_ (AES_192_CTR, AES_CTR, 24, SHA1, 12) \
_ (AES_256_CTR, AES_CTR, 32, SHA1, 12)
typedef enum
{
CRYPTODEV_OP_TYPE_ENCRYPT = 0,
CRYPTODEV_OP_TYPE_DECRYPT,
CRYPTODEV_N_OP_TYPES,
} cryptodev_op_type_t;
#if RTE_VERSION >= RTE_VERSION_NUM(22, 11, 0, 0)
typedef void cryptodev_session_t;
#else
typedef struct rte_cryptodev_sym_session cryptodev_session_t;
#endif
/* Cryptodev session data, one data per direction per numa */
typedef struct
{
cryptodev_session_t ***keys;
} cryptodev_key_t;
/* Replicate DPDK rte_cryptodev_sym_capability structure with key size ranges
* in favor of vpp vector */
typedef struct
{
enum rte_crypto_sym_xform_type xform_type;
union
{
struct
{
enum rte_crypto_auth_algorithm algo; /*auth algo */
u32 *digest_sizes; /* vector of auth digest sizes */
} auth;
struct
{
enum rte_crypto_cipher_algorithm algo; /* cipher algo */
u32 *key_sizes; /* vector of cipher key sizes */
} cipher;
struct
{
enum rte_crypto_aead_algorithm algo; /* aead algo */
u32 *key_sizes; /*vector of aead key sizes */
u32 *aad_sizes; /*vector of aad sizes */
u32 *digest_sizes; /* vector of aead digest sizes */
} aead;
};
} cryptodev_capability_t;
/* Cryptodev instance data */
typedef struct
{
u32 dev_id;
u32 q_id;
char *desc;
} cryptodev_inst_t;
typedef struct
{
struct rte_mempool *sess_pool;
#if RTE_VERSION < RTE_VERSION_NUM(22, 11, 0, 0)
struct rte_mempool *sess_priv_pool;
#endif
} cryptodev_session_pool_t;
typedef struct
{
cryptodev_session_pool_t *sess_pools;
} cryptodev_numa_data_t;
typedef struct
{
CLIB_CACHE_LINE_ALIGN_MARK (cacheline0);
struct rte_crypto_op op;
struct rte_crypto_sym_op sop;
u8 iv[CRYPTODEV_MAX_IV_SIZE];
u8 aad[CRYPTODEV_MAX_AAD_SIZE];
vnet_crypto_async_frame_t *frame;
u32 n_elts;
} cryptodev_op_t;
typedef struct
{
vnet_crypto_async_frame_t *f;
union
{
struct
{
/* index of frame elt where enque to
* the crypto engine is happening */
u8 enq_elts_head;
/* index of the frame elt where dequeue
* from the crypto engine is happening */
u8 deq_elts_tail;
u8 elts_inflight;
u8 op_type;
u8 aad_len;
u8 n_elts;
u16 reserved;
};
u64 raw;
};
u64 frame_elts_errs_mask;
} cryptodev_cache_ring_elt_t;
typedef struct
{
cryptodev_cache_ring_elt_t frames[VNET_CRYPTO_FRAME_POOL_SIZE];
union
{
struct
{
/* head of the cache ring */
u16 head;
/* tail of the cache ring */
u16 tail;
/* index of the frame where enqueue
* to the crypto engine is happening */
u16 enq_head;
/* index of the frame where dequeue
* from the crypto engine is happening */
u16 deq_tail;
};
u64 raw;
};
} cryptodev_cache_ring_t;
typedef struct
{
CLIB_CACHE_LINE_ALIGN_MARK (cacheline0);
vlib_buffer_t *b[VNET_CRYPTO_FRAME_SIZE];
union
{
struct rte_mempool *cop_pool;
struct
{
struct rte_crypto_raw_dp_ctx *ctx;
u16 aad_index;
u8 *aad_buf;
u64 aad_phy_addr;
cryptodev_session_t *reset_sess;
};
};
cryptodev_cache_ring_t cache_ring;
u16 cryptodev_id;
u16 cryptodev_q;
u16 inflight;
} cryptodev_engine_thread_t;
typedef struct
{
cryptodev_numa_data_t *per_numa_data;
cryptodev_key_t *keys;
cryptodev_engine_thread_t *per_thread_data;
enum rte_iova_mode iova_mode;
cryptodev_inst_t *cryptodev_inst;
clib_bitmap_t *active_cdev_inst_mask;
clib_spinlock_t tlock;
cryptodev_capability_t *supported_caps;
u32 sess_sz;
u32 drivers_cnt;
u8 is_raw_api;
#if RTE_VERSION >= RTE_VERSION_NUM(22, 11, 0, 0)
u8 driver_id;
#endif
} cryptodev_main_t;
extern cryptodev_main_t cryptodev_main;
#define CRYPTODEV_CACHE_RING_GET_FRAME(r, i) \
((r)->frames[(i) &CRYPTODEV_CACHE_QUEUE_MASK].f)
#define CRYPTODEV_CACHE_RING_GET_ERR_MASK(r, i) \
((r)->frames[(i) &CRYPTODEV_CACHE_QUEUE_MASK].frame_elts_errs_mask)
#define CRYPTODEV_CACHE_RING_GET_FRAME_ELTS_INFLIGHT(r, i) \
(((r)->frames[(i) &CRYPTODEV_CACHE_QUEUE_MASK].enq_elts_head) - \
((r)->frames[(i) &CRYPTODEV_CACHE_QUEUE_MASK].deq_elts_tail))
static_always_inline void
cryptodev_cache_ring_update_enq_head (cryptodev_cache_ring_t *r,
vnet_crypto_async_frame_t *f)
{
if (r->frames[r->enq_head].enq_elts_head == f->n_elts)
{
r->enq_head++;
r->enq_head &= CRYPTODEV_CACHE_QUEUE_MASK;
f->state = VNET_CRYPTO_FRAME_STATE_NOT_PROCESSED;
}
}
static_always_inline bool
cryptodev_cache_ring_update_deq_tail (cryptodev_cache_ring_t *r,
u16 *const deq)
{
if (r->frames[*deq].deq_elts_tail == r->frames[*deq].n_elts)
{
*deq += 1;
*deq &= CRYPTODEV_CACHE_QUEUE_MASK;
return 1;
}
return 0;
}
static_always_inline u64
cryptodev_mark_frame_fill_err (vnet_crypto_async_frame_t *f, u64 current_err,
u16 index, u16 n, vnet_crypto_op_status_t op_s)
{
u64 err = current_err;
u16 i;
ERROR_ASSERT (index + n <= VNET_CRYPTO_FRAME_SIZE);
ERROR_ASSERT (op_s != VNET_CRYPTO_OP_STATUS_COMPLETED);
for (i = index; i < (index + n); i++)
f->elts[i].status = op_s;
err |= (~(~(0ull) << n) << index);
return err;
}
static_always_inline cryptodev_cache_ring_elt_t *
cryptodev_cache_ring_push (cryptodev_cache_ring_t *r,
vnet_crypto_async_frame_t *f)
{
u16 head = r->head;
u16 tail = r->tail;
cryptodev_cache_ring_elt_t *ring_elt = &r->frames[head];
/**
* in debug mode we do the ring sanity test when a frame is enqueued to
* the ring.
**/
#if CLIB_DEBUG > 0
u16 n_cached = (head >= tail) ? (head - tail) :
(CRYPTODEV_CACHE_QUEUE_MASK - tail + head);
ERROR_ASSERT (n_cached < CRYPTODEV_CACHE_QUEUE_SIZE);
ERROR_ASSERT (r->raw == 0 && r->frames[head].raw == 0 &&
r->frames[head].f == 0);
#endif
/*the ring capacity is CRYPTODEV_CACHE_QUEUE_SIZE - 1*/
if (PREDICT_FALSE (head + 1) == tail)
return 0;
ring_elt->f = f;
ring_elt->n_elts = f->n_elts;
/* update head */
r->head++;
r->head &= CRYPTODEV_CACHE_QUEUE_MASK;
return ring_elt;
}
static_always_inline vnet_crypto_async_frame_t *
cryptodev_cache_ring_pop (cryptodev_cache_ring_t *r)
{
vnet_crypto_async_frame_t *f;
u16 tail = r->tail;
cryptodev_cache_ring_elt_t *ring_elt = &r->frames[tail];
ERROR_ASSERT (r->frames[r->head].raw == 0 ? r->head != tail : 1);
ERROR_ASSERT (r->frames[tail].raw != 0);
ERROR_ASSERT (ring_elt->deq_elts_tail == ring_elt->enq_elts_head &&
ring_elt->deq_elts_tail == ring_elt->n_elts);
f = CRYPTODEV_CACHE_RING_GET_FRAME (r, tail);
f->state = CRYPTODEV_CACHE_RING_GET_ERR_MASK (r, r->tail) == 0 ?
VNET_CRYPTO_FRAME_STATE_SUCCESS :
VNET_CRYPTO_FRAME_STATE_ELT_ERROR;
clib_memset (ring_elt, 0, sizeof (*ring_elt));
r->tail++;
r->tail &= CRYPTODEV_CACHE_QUEUE_MASK;
return f;
}
int cryptodev_session_create (vlib_main_t *vm, vnet_crypto_key_index_t idx,
u32 aad_len);
void cryptodev_sess_handler (vlib_main_t *vm, vnet_crypto_key_op_t kop,
vnet_crypto_key_index_t idx, u32 aad_len);
int cryptodev_check_cap_support (struct rte_cryptodev_sym_capability_idx *idx,
u32 key_size, u32 digest_size, u32 aad_size);
clib_error_t *cryptodev_register_cop_hdl (vlib_main_t *vm, u32 eidx);
clib_error_t *__clib_weak cryptodev_register_raw_hdl (vlib_main_t *vm,
u32 eidx);
clib_error_t *__clib_weak dpdk_cryptodev_init (vlib_main_t *vm);
#endif
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