/* SPDX-License-Identifier: BSD-3-Clause * Copyright(c) 2018 Cavium, Inc */ #include #include #include #include #include #include #include #include "otx_cryptodev.h" #include "otx_cryptodev_capabilities.h" #include "otx_cryptodev_hw_access.h" #include "otx_cryptodev_mbox.h" #include "otx_cryptodev_ops.h" #include "cpt_pmd_logs.h" #include "cpt_ucode.h" #include "cpt_ucode_asym.h" /* Forward declarations */ static int otx_cpt_que_pair_release(struct rte_cryptodev *dev, uint16_t que_pair_id); /* Alarm routines */ static void otx_cpt_alarm_cb(void *arg) { struct cpt_vf *cptvf = arg; otx_cpt_poll_misc(cptvf); rte_eal_alarm_set(CPT_INTR_POLL_INTERVAL_MS * 1000, otx_cpt_alarm_cb, cptvf); } static int otx_cpt_periodic_alarm_start(void *arg) { return rte_eal_alarm_set(CPT_INTR_POLL_INTERVAL_MS * 1000, otx_cpt_alarm_cb, arg); } static int otx_cpt_periodic_alarm_stop(void *arg) { return rte_eal_alarm_cancel(otx_cpt_alarm_cb, arg); } /* PMD ops */ static int otx_cpt_dev_config(struct rte_cryptodev *dev __rte_unused, struct rte_cryptodev_config *config __rte_unused) { CPT_PMD_INIT_FUNC_TRACE(); return 0; } static int otx_cpt_dev_start(struct rte_cryptodev *c_dev) { void *cptvf = c_dev->data->dev_private; CPT_PMD_INIT_FUNC_TRACE(); return otx_cpt_start_device(cptvf); } static void otx_cpt_dev_stop(struct rte_cryptodev *c_dev) { void *cptvf = c_dev->data->dev_private; CPT_PMD_INIT_FUNC_TRACE(); otx_cpt_stop_device(cptvf); } static int otx_cpt_dev_close(struct rte_cryptodev *c_dev) { void *cptvf = c_dev->data->dev_private; int i, ret; CPT_PMD_INIT_FUNC_TRACE(); for (i = 0; i < c_dev->data->nb_queue_pairs; i++) { ret = otx_cpt_que_pair_release(c_dev, i); if (ret) return ret; } otx_cpt_periodic_alarm_stop(cptvf); otx_cpt_deinit_device(cptvf); return 0; } static void otx_cpt_dev_info_get(struct rte_cryptodev *dev, struct rte_cryptodev_info *info) { CPT_PMD_INIT_FUNC_TRACE(); if (info != NULL) { info->max_nb_queue_pairs = CPT_NUM_QS_PER_VF; info->feature_flags = dev->feature_flags; info->capabilities = otx_get_capabilities(info->feature_flags); info->sym.max_nb_sessions = 0; info->driver_id = otx_cryptodev_driver_id; info->min_mbuf_headroom_req = OTX_CPT_MIN_HEADROOM_REQ; info->min_mbuf_tailroom_req = OTX_CPT_MIN_TAILROOM_REQ; } } static void otx_cpt_stats_get(struct rte_cryptodev *dev __rte_unused, struct rte_cryptodev_stats *stats __rte_unused) { CPT_PMD_INIT_FUNC_TRACE(); } static void otx_cpt_stats_reset(struct rte_cryptodev *dev __rte_unused) { CPT_PMD_INIT_FUNC_TRACE(); } static int otx_cpt_que_pair_setup(struct rte_cryptodev *dev, uint16_t que_pair_id, const struct rte_cryptodev_qp_conf *qp_conf, int socket_id __rte_unused) { struct cpt_instance *instance = NULL; struct rte_pci_device *pci_dev; int ret = -1; CPT_PMD_INIT_FUNC_TRACE(); if (dev->data->queue_pairs[que_pair_id] != NULL) { ret = otx_cpt_que_pair_release(dev, que_pair_id); if (ret) return ret; } if (qp_conf->nb_descriptors > DEFAULT_CMD_QLEN) { CPT_LOG_INFO("Number of descriptors too big %d, using default " "queue length of %d", qp_conf->nb_descriptors, DEFAULT_CMD_QLEN); } pci_dev = RTE_DEV_TO_PCI(dev->device); if (pci_dev->mem_resource[0].addr == NULL) { CPT_LOG_ERR("PCI mem address null"); return -EIO; } ret = otx_cpt_get_resource(dev, 0, &instance, que_pair_id); if (ret != 0 || instance == NULL) { CPT_LOG_ERR("Error getting instance handle from device %s : " "ret = %d", dev->data->name, ret); return ret; } instance->queue_id = que_pair_id; instance->sess_mp = qp_conf->mp_session; instance->sess_mp_priv = qp_conf->mp_session_private; dev->data->queue_pairs[que_pair_id] = instance; return 0; } static int otx_cpt_que_pair_release(struct rte_cryptodev *dev, uint16_t que_pair_id) { struct cpt_instance *instance = dev->data->queue_pairs[que_pair_id]; int ret; CPT_PMD_INIT_FUNC_TRACE(); ret = otx_cpt_put_resource(instance); if (ret != 0) { CPT_LOG_ERR("Error putting instance handle of device %s : " "ret = %d", dev->data->name, ret); return ret; } dev->data->queue_pairs[que_pair_id] = NULL; return 0; } static unsigned int otx_cpt_get_session_size(struct rte_cryptodev *dev __rte_unused) { return cpt_get_session_size(); } static void otx_cpt_session_init(void *sym_sess, uint8_t driver_id) { struct rte_cryptodev_sym_session *sess = sym_sess; struct cpt_sess_misc *cpt_sess = (struct cpt_sess_misc *) get_sym_session_private_data(sess, driver_id); CPT_PMD_INIT_FUNC_TRACE(); cpt_sess->ctx_dma_addr = rte_mempool_virt2iova(cpt_sess) + sizeof(struct cpt_sess_misc); } static int otx_cpt_session_cfg(struct rte_cryptodev *dev, struct rte_crypto_sym_xform *xform, struct rte_cryptodev_sym_session *sess, struct rte_mempool *mempool) { struct rte_crypto_sym_xform *chain; void *sess_private_data = NULL; CPT_PMD_INIT_FUNC_TRACE(); if (cpt_is_algo_supported(xform)) goto err; if (unlikely(sess == NULL)) { CPT_LOG_ERR("invalid session struct"); return -EINVAL; } if (rte_mempool_get(mempool, &sess_private_data)) { CPT_LOG_ERR("Could not allocate sess_private_data"); return -ENOMEM; } chain = xform; while (chain) { switch (chain->type) { case RTE_CRYPTO_SYM_XFORM_AEAD: if (fill_sess_aead(chain, sess_private_data)) goto err; break; case RTE_CRYPTO_SYM_XFORM_CIPHER: if (fill_sess_cipher(chain, sess_private_data)) goto err; break; case RTE_CRYPTO_SYM_XFORM_AUTH: if (chain->auth.algo == RTE_CRYPTO_AUTH_AES_GMAC) { if (fill_sess_gmac(chain, sess_private_data)) goto err; } else { if (fill_sess_auth(chain, sess_private_data)) goto err; } break; default: CPT_LOG_ERR("Invalid crypto xform type"); break; } chain = chain->next; } set_sym_session_private_data(sess, dev->driver_id, sess_private_data); otx_cpt_session_init(sess, dev->driver_id); return 0; err: if (sess_private_data) rte_mempool_put(mempool, sess_private_data); return -EPERM; } static void otx_cpt_session_clear(struct rte_cryptodev *dev, struct rte_cryptodev_sym_session *sess) { void *sess_priv = get_sym_session_private_data(sess, dev->driver_id); CPT_PMD_INIT_FUNC_TRACE(); if (sess_priv) { memset(sess_priv, 0, otx_cpt_get_session_size(dev)); struct rte_mempool *sess_mp = rte_mempool_from_obj(sess_priv); set_sym_session_private_data(sess, dev->driver_id, NULL); rte_mempool_put(sess_mp, sess_priv); } } static unsigned int otx_cpt_asym_session_size_get(struct rte_cryptodev *dev __rte_unused) { return sizeof(struct cpt_asym_sess_misc); } static int otx_cpt_asym_session_cfg(struct rte_cryptodev *dev, struct rte_crypto_asym_xform *xform __rte_unused, struct rte_cryptodev_asym_session *sess, struct rte_mempool *pool) { struct cpt_asym_sess_misc *priv; int ret; CPT_PMD_INIT_FUNC_TRACE(); if (rte_mempool_get(pool, (void **)&priv)) { CPT_LOG_ERR("Could not allocate session private data"); return -ENOMEM; } memset(priv, 0, sizeof(struct cpt_asym_sess_misc)); ret = cpt_fill_asym_session_parameters(priv, xform); if (ret) { CPT_LOG_ERR("Could not configure session parameters"); /* Return session to mempool */ rte_mempool_put(pool, priv); return ret; } set_asym_session_private_data(sess, dev->driver_id, priv); return 0; } static void otx_cpt_asym_session_clear(struct rte_cryptodev *dev, struct rte_cryptodev_asym_session *sess) { struct cpt_asym_sess_misc *priv; struct rte_mempool *sess_mp; CPT_PMD_INIT_FUNC_TRACE(); priv = get_asym_session_private_data(sess, dev->driver_id); if (priv == NULL) return; /* Free resources allocated during session configure */ cpt_free_asym_session_parameters(priv); memset(priv, 0, otx_cpt_asym_session_size_get(dev)); sess_mp = rte_mempool_from_obj(priv); set_asym_session_private_data(sess, dev->driver_id, NULL); rte_mempool_put(sess_mp, priv); } static __rte_always_inline int32_t __hot otx_cpt_request_enqueue(struct cpt_instance *instance, struct pending_queue *pqueue, void *req) { struct cpt_request_info *user_req = (struct cpt_request_info *)req; if (unlikely(pqueue->pending_count >= DEFAULT_CMD_QLEN)) return -EAGAIN; fill_cpt_inst(instance, req); CPT_LOG_DP_DEBUG("req: %p op: %p ", req, user_req->op); /* Fill time_out cycles */ user_req->time_out = rte_get_timer_cycles() + DEFAULT_COMMAND_TIMEOUT * rte_get_timer_hz(); user_req->extra_time = 0; /* Default mode of software queue */ mark_cpt_inst(instance); pqueue->rid_queue[pqueue->enq_tail].rid = (uintptr_t)user_req; /* We will use soft queue length here to limit requests */ MOD_INC(pqueue->enq_tail, DEFAULT_CMD_QLEN); pqueue->pending_count += 1; CPT_LOG_DP_DEBUG("Submitted NB cmd with request: %p " "op: %p", user_req, user_req->op); return 0; } static __rte_always_inline int __hot otx_cpt_enq_single_asym(struct cpt_instance *instance, struct rte_crypto_op *op, struct pending_queue *pqueue) { struct cpt_qp_meta_info *minfo = &instance->meta_info; struct rte_crypto_asym_op *asym_op = op->asym; struct asym_op_params params = {0}; struct cpt_asym_sess_misc *sess; uintptr_t *cop; void *mdata; int ret; if (unlikely(rte_mempool_get(minfo->pool, &mdata) < 0)) { CPT_LOG_DP_ERR("Could not allocate meta buffer for request"); return -ENOMEM; } sess = get_asym_session_private_data(asym_op->session, otx_cryptodev_driver_id); /* Store phys_addr of the mdata to meta_buf */ params.meta_buf = rte_mempool_virt2iova(mdata); cop = mdata; cop[0] = (uintptr_t)mdata; cop[1] = (uintptr_t)op; cop[2] = cop[3] = 0ULL; params.req = RTE_PTR_ADD(cop, 4 * sizeof(uintptr_t)); params.req->op = cop; /* Adjust meta_buf by crypto_op data and request_info struct */ params.meta_buf += (4 * sizeof(uintptr_t)) + sizeof(struct cpt_request_info); switch (sess->xfrm_type) { case RTE_CRYPTO_ASYM_XFORM_MODEX: ret = cpt_modex_prep(¶ms, &sess->mod_ctx); if (unlikely(ret)) goto req_fail; break; case RTE_CRYPTO_ASYM_XFORM_RSA: ret = cpt_enqueue_rsa_op(op, ¶ms, sess); if (unlikely(ret)) goto req_fail; break; default: op->status = RTE_CRYPTO_OP_STATUS_INVALID_ARGS; ret = -EINVAL; goto req_fail; } ret = otx_cpt_request_enqueue(instance, pqueue, params.req); if (unlikely(ret)) { CPT_LOG_DP_ERR("Could not enqueue crypto req"); goto req_fail; } return 0; req_fail: free_op_meta(mdata, minfo->pool); return ret; } static __rte_always_inline int __hot otx_cpt_enq_single_sym(struct cpt_instance *instance, struct rte_crypto_op *op, struct pending_queue *pqueue) { struct cpt_sess_misc *sess; struct rte_crypto_sym_op *sym_op = op->sym; void *prep_req, *mdata = NULL; int ret = 0; uint64_t cpt_op; sess = (struct cpt_sess_misc *) get_sym_session_private_data(sym_op->session, otx_cryptodev_driver_id); cpt_op = sess->cpt_op; if (likely(cpt_op & CPT_OP_CIPHER_MASK)) ret = fill_fc_params(op, sess, &instance->meta_info, &mdata, &prep_req); else ret = fill_digest_params(op, sess, &instance->meta_info, &mdata, &prep_req); if (unlikely(ret)) { CPT_LOG_DP_ERR("prep cryto req : op %p, cpt_op 0x%x " "ret 0x%x", op, (unsigned int)cpt_op, ret); return ret; } /* Enqueue prepared instruction to h/w */ ret = otx_cpt_request_enqueue(instance, pqueue, prep_req); if (unlikely(ret)) { /* Buffer allocated for request preparation need to be freed */ free_op_meta(mdata, instance->meta_info.pool); return ret; } return 0; } static __rte_always_inline int __hot otx_cpt_enq_single_sym_sessless(struct cpt_instance *instance, struct rte_crypto_op *op, struct pending_queue *pqueue) { struct cpt_sess_misc *sess; struct rte_crypto_sym_op *sym_op = op->sym; int ret; void *sess_t = NULL; void *sess_private_data_t = NULL; /* Create tmp session */ if (rte_mempool_get(instance->sess_mp, (void **)&sess_t)) { ret = -ENOMEM; goto exit; } if (rte_mempool_get(instance->sess_mp_priv, (void **)&sess_private_data_t)) { ret = -ENOMEM; goto free_sess; } sess = (struct cpt_sess_misc *)sess_private_data_t; sess->ctx_dma_addr = rte_mempool_virt2iova(sess) + sizeof(struct cpt_sess_misc); ret = instance_session_cfg(sym_op->xform, (void *)sess); if (unlikely(ret)) { ret = -EINVAL; goto free_sess_priv; } /* Save tmp session in op */ sym_op->session = (struct rte_cryptodev_sym_session *)sess_t; set_sym_session_private_data(sym_op->session, otx_cryptodev_driver_id, sess_private_data_t); /* Enqueue op with the tmp session set */ ret = otx_cpt_enq_single_sym(instance, op, pqueue); if (unlikely(ret)) goto free_sess_priv; return 0; free_sess_priv: rte_mempool_put(instance->sess_mp_priv, sess_private_data_t); free_sess: rte_mempool_put(instance->sess_mp, sess_t); exit: return ret; } #define OP_TYPE_SYM 0 #define OP_TYPE_ASYM 1 static __rte_always_inline int __hot otx_cpt_enq_single(struct cpt_instance *inst, struct rte_crypto_op *op, struct pending_queue *pqueue, const uint8_t op_type) { /* Check for the type */ if (op_type == OP_TYPE_SYM) { if (op->sess_type == RTE_CRYPTO_OP_WITH_SESSION) return otx_cpt_enq_single_sym(inst, op, pqueue); else return otx_cpt_enq_single_sym_sessless(inst, op, pqueue); } if (op_type == OP_TYPE_ASYM) { if (op->sess_type == RTE_CRYPTO_OP_WITH_SESSION) return otx_cpt_enq_single_asym(inst, op, pqueue); } /* Should not reach here */ return -ENOTSUP; } static __rte_always_inline uint16_t __hot otx_cpt_pkt_enqueue(void *qptr, struct rte_crypto_op **ops, uint16_t nb_ops, const uint8_t op_type) { struct cpt_instance *instance = (struct cpt_instance *)qptr; uint16_t count; int ret; struct cpt_vf *cptvf = (struct cpt_vf *)instance; struct pending_queue *pqueue = &cptvf->pqueue; count = DEFAULT_CMD_QLEN - pqueue->pending_count; if (nb_ops > count) nb_ops = count; count = 0; while (likely(count < nb_ops)) { /* Enqueue single op */ ret = otx_cpt_enq_single(instance, ops[count], pqueue, op_type); if (unlikely(ret)) break; count++; } otx_cpt_ring_dbell(instance, count); return count; } static uint16_t otx_cpt_enqueue_asym(void *qptr, struct rte_crypto_op **ops, uint16_t nb_ops) { return otx_cpt_pkt_enqueue(qptr, ops, nb_ops, OP_TYPE_ASYM); } static uint16_t otx_cpt_enqueue_sym(void *qptr, struct rte_crypto_op **ops, uint16_t nb_ops) { return otx_cpt_pkt_enqueue(qptr, ops, nb_ops, OP_TYPE_SYM); } static inline void otx_cpt_asym_rsa_op(struct rte_crypto_op *cop, struct cpt_request_info *req, struct rte_crypto_rsa_xform *rsa_ctx) { struct rte_crypto_rsa_op_param *rsa = &cop->asym->rsa; switch (rsa->op_type) { case RTE_CRYPTO_ASYM_OP_ENCRYPT: rsa->cipher.length = rsa_ctx->n.length; memcpy(rsa->cipher.data, req->rptr, rsa->cipher.length); break; case RTE_CRYPTO_ASYM_OP_DECRYPT: if (rsa->pad == RTE_CRYPTO_RSA_PADDING_NONE) rsa->message.length = rsa_ctx->n.length; else { /* Get length of decrypted output */ rsa->message.length = rte_cpu_to_be_16 (*((uint16_t *)req->rptr)); /* Offset data pointer by length fields */ req->rptr += 2; } memcpy(rsa->message.data, req->rptr, rsa->message.length); break; case RTE_CRYPTO_ASYM_OP_SIGN: rsa->sign.length = rsa_ctx->n.length; memcpy(rsa->sign.data, req->rptr, rsa->sign.length); break; case RTE_CRYPTO_ASYM_OP_VERIFY: if (rsa->pad == RTE_CRYPTO_RSA_PADDING_NONE) rsa->sign.length = rsa_ctx->n.length; else { /* Get length of decrypted output */ rsa->sign.length = rte_cpu_to_be_16 (*((uint16_t *)req->rptr)); /* Offset data pointer by length fields */ req->rptr += 2; } memcpy(rsa->sign.data, req->rptr, rsa->sign.length); if (memcmp(rsa->sign.data, rsa->message.data, rsa->message.length)) { CPT_LOG_DP_ERR("RSA verification failed"); cop->status = RTE_CRYPTO_OP_STATUS_ERROR; } break; default: CPT_LOG_DP_DEBUG("Invalid RSA operation type"); cop->status = RTE_CRYPTO_OP_STATUS_INVALID_ARGS; break; } } static __rte_always_inline void __hot otx_cpt_asym_post_process(struct rte_crypto_op *cop, struct cpt_request_info *req) { struct rte_crypto_asym_op *op = cop->asym; struct cpt_asym_sess_misc *sess; sess = get_asym_session_private_data(op->session, otx_cryptodev_driver_id); switch (sess->xfrm_type) { case RTE_CRYPTO_ASYM_XFORM_RSA: otx_cpt_asym_rsa_op(cop, req, &sess->rsa_ctx); break; case RTE_CRYPTO_ASYM_XFORM_MODEX: op->modex.result.length = sess->mod_ctx.modulus.length; memcpy(op->modex.result.data, req->rptr, op->modex.result.length); break; default: CPT_LOG_DP_DEBUG("Invalid crypto xform type"); cop->status = RTE_CRYPTO_OP_STATUS_INVALID_ARGS; break; } } static __rte_always_inline void __hot otx_cpt_dequeue_post_process(struct rte_crypto_op *cop, uintptr_t *rsp, const uint8_t op_type) { /* H/w has returned success */ cop->status = RTE_CRYPTO_OP_STATUS_SUCCESS; /* Perform further post processing */ if ((op_type == OP_TYPE_SYM) && (cop->type == RTE_CRYPTO_OP_TYPE_SYMMETRIC)) { /* Check if auth verify need to be completed */ if (unlikely(rsp[2])) compl_auth_verify(cop, (uint8_t *)rsp[2], rsp[3]); return; } if ((op_type == OP_TYPE_ASYM) && (cop->type == RTE_CRYPTO_OP_TYPE_ASYMMETRIC)) { rsp = RTE_PTR_ADD(rsp, 4 * sizeof(uintptr_t)); otx_cpt_asym_post_process(cop, (struct cpt_request_info *)rsp); } return; } static __rte_always_inline uint16_t __hot otx_cpt_pkt_dequeue(void *qptr, struct rte_crypto_op **ops, uint16_t nb_ops, const uint8_t op_type) { struct cpt_instance *instance = (struct cpt_instance *)qptr; struct cpt_request_info *user_req; struct cpt_vf *cptvf = (struct cpt_vf *)instance; struct rid *rid_e; uint8_t cc[nb_ops]; int i, count, pcount; uint8_t ret; int nb_completed; struct pending_queue *pqueue = &cptvf->pqueue; struct rte_crypto_op *cop; void *metabuf; uintptr_t *rsp; pcount = pqueue->pending_count; count = (nb_ops > pcount) ? pcount : nb_ops; for (i = 0; i < count; i++) { rid_e = &pqueue->rid_queue[pqueue->deq_head]; user_req = (struct cpt_request_info *)(rid_e->rid); if (likely((i+1) < count)) rte_prefetch_non_temporal((void *)rid_e[1].rid); ret = check_nb_command_id(user_req, instance); if (unlikely(ret == ERR_REQ_PENDING)) { /* Stop checking for completions */ break; } /* Return completion code and op handle */ cc[i] = ret; ops[i] = user_req->op; CPT_LOG_DP_DEBUG("Request %p Op %p completed with code %d", user_req, user_req->op, ret); MOD_INC(pqueue->deq_head, DEFAULT_CMD_QLEN); pqueue->pending_count -= 1; } nb_completed = i; for (i = 0; i < nb_completed; i++) { rsp = (void *)ops[i]; if (likely((i + 1) < nb_completed)) rte_prefetch0(ops[i+1]); metabuf = (void *)rsp[0]; cop = (void *)rsp[1]; ops[i] = cop; /* Check completion code */ if (likely(cc[i] == 0)) { /* H/w success pkt. Post process */ otx_cpt_dequeue_post_process(cop, rsp, op_type); } else if (cc[i] == ERR_GC_ICV_MISCOMPARE) { /* auth data mismatch */ cop->status = RTE_CRYPTO_OP_STATUS_AUTH_FAILED; } else { /* Error */ cop->status = RTE_CRYPTO_OP_STATUS_ERROR; } if (unlikely(cop->sess_type == RTE_CRYPTO_OP_SESSIONLESS)) { void *sess_private_data_t = get_sym_session_private_data(cop->sym->session, otx_cryptodev_driver_id); memset(sess_private_data_t, 0, cpt_get_session_size()); memset(cop->sym->session, 0, rte_cryptodev_sym_get_existing_header_session_size( cop->sym->session)); rte_mempool_put(instance->sess_mp_priv, sess_private_data_t); rte_mempool_put(instance->sess_mp, cop->sym->session); cop->sym->session = NULL; } free_op_meta(metabuf, instance->meta_info.pool); } return nb_completed; } static uint16_t otx_cpt_dequeue_asym(void *qptr, struct rte_crypto_op **ops, uint16_t nb_ops) { return otx_cpt_pkt_dequeue(qptr, ops, nb_ops, OP_TYPE_ASYM); } static uint16_t otx_cpt_dequeue_sym(void *qptr, struct rte_crypto_op **ops, uint16_t nb_ops) { return otx_cpt_pkt_dequeue(qptr, ops, nb_ops, OP_TYPE_SYM); } static struct rte_cryptodev_ops cptvf_ops = { /* Device related operations */ .dev_configure = otx_cpt_dev_config, .dev_start = otx_cpt_dev_start, .dev_stop = otx_cpt_dev_stop, .dev_close = otx_cpt_dev_close, .dev_infos_get = otx_cpt_dev_info_get, .stats_get = otx_cpt_stats_get, .stats_reset = otx_cpt_stats_reset, .queue_pair_setup = otx_cpt_que_pair_setup, .queue_pair_release = otx_cpt_que_pair_release, .queue_pair_count = NULL, /* Crypto related operations */ .sym_session_get_size = otx_cpt_get_session_size, .sym_session_configure = otx_cpt_session_cfg, .sym_session_clear = otx_cpt_session_clear, .asym_session_get_size = otx_cpt_asym_session_size_get, .asym_session_configure = otx_cpt_asym_session_cfg, .asym_session_clear = otx_cpt_asym_session_clear, }; int otx_cpt_dev_create(struct rte_cryptodev *c_dev) { struct rte_pci_device *pdev = RTE_DEV_TO_PCI(c_dev->device); struct cpt_vf *cptvf = NULL; void *reg_base; char dev_name[32]; int ret; if (pdev->mem_resource[0].phys_addr == 0ULL) return -EIO; /* for secondary processes, we don't initialise any further as primary * has already done this work. */ if (rte_eal_process_type() != RTE_PROC_PRIMARY) return 0; cptvf = rte_zmalloc_socket("otx_cryptodev_private_mem", sizeof(struct cpt_vf), RTE_CACHE_LINE_SIZE, rte_socket_id()); if (cptvf == NULL) { CPT_LOG_ERR("Cannot allocate memory for device private data"); return -ENOMEM; } snprintf(dev_name, 32, "%02x:%02x.%x", pdev->addr.bus, pdev->addr.devid, pdev->addr.function); reg_base = pdev->mem_resource[0].addr; if (!reg_base) { CPT_LOG_ERR("Failed to map BAR0 of %s", dev_name); ret = -ENODEV; goto fail; } ret = otx_cpt_hw_init(cptvf, pdev, reg_base, dev_name); if (ret) { CPT_LOG_ERR("Failed to init cptvf %s", dev_name); ret = -EIO; goto fail; } switch (cptvf->vftype) { case OTX_CPT_VF_TYPE_AE: /* Set asymmetric cpt feature flags */ c_dev->feature_flags = RTE_CRYPTODEV_FF_ASYMMETRIC_CRYPTO | RTE_CRYPTODEV_FF_HW_ACCELERATED | RTE_CRYPTODEV_FF_RSA_PRIV_OP_KEY_QT; break; case OTX_CPT_VF_TYPE_SE: /* Set symmetric cpt feature flags */ c_dev->feature_flags = RTE_CRYPTODEV_FF_SYMMETRIC_CRYPTO | RTE_CRYPTODEV_FF_HW_ACCELERATED | RTE_CRYPTODEV_FF_SYM_OPERATION_CHAINING | RTE_CRYPTODEV_FF_IN_PLACE_SGL | RTE_CRYPTODEV_FF_OOP_LB_IN_LB_OUT | RTE_CRYPTODEV_FF_OOP_SGL_IN_LB_OUT | RTE_CRYPTODEV_FF_OOP_SGL_IN_SGL_OUT; break; default: /* Feature not supported. Abort */ CPT_LOG_ERR("VF type not supported by %s", dev_name); ret = -EIO; goto deinit_dev; } /* Start off timer for mailbox interrupts */ otx_cpt_periodic_alarm_start(cptvf); c_dev->dev_ops = &cptvf_ops; if (c_dev->feature_flags & RTE_CRYPTODEV_FF_SYMMETRIC_CRYPTO) { c_dev->enqueue_burst = otx_cpt_enqueue_sym; c_dev->dequeue_burst = otx_cpt_dequeue_sym; } else { c_dev->enqueue_burst = otx_cpt_enqueue_asym; c_dev->dequeue_burst = otx_cpt_dequeue_asym; } /* Save dev private data */ c_dev->data->dev_private = cptvf; return 0; deinit_dev: otx_cpt_deinit_device(cptvf); fail: if (cptvf) { /* Free private data allocated */ rte_free(cptvf); } return ret; }