/* SPDX-License-Identifier: BSD-3-Clause * Copyright(c) 2018-2020 Intel Corporation */ #include #include #include #include #include #include #include "sa.h" #include "ipsec_sqn.h" #include "crypto.h" #include "iph.h" #include "misc.h" #include "pad.h" typedef int32_t (*esp_outb_prepare_t)(struct rte_ipsec_sa *sa, rte_be64_t sqc, const uint64_t ivp[IPSEC_MAX_IV_QWORD], struct rte_mbuf *mb, union sym_op_data *icv, uint8_t sqh_len, uint8_t tso); /* * helper function to fill crypto_sym op for cipher+auth algorithms. * used by outb_cop_prepare(), see below. */ static inline void sop_ciph_auth_prepare(struct rte_crypto_sym_op *sop, const struct rte_ipsec_sa *sa, const union sym_op_data *icv, uint32_t pofs, uint32_t plen) { sop->cipher.data.offset = sa->ctp.cipher.offset + pofs; sop->cipher.data.length = sa->ctp.cipher.length + plen; sop->auth.data.offset = sa->ctp.auth.offset + pofs; sop->auth.data.length = sa->ctp.auth.length + plen; sop->auth.digest.data = icv->va; sop->auth.digest.phys_addr = icv->pa; } /* * helper function to fill crypto_sym op for cipher+auth algorithms. * used by outb_cop_prepare(), see below. */ static inline void sop_aead_prepare(struct rte_crypto_sym_op *sop, const struct rte_ipsec_sa *sa, const union sym_op_data *icv, uint32_t pofs, uint32_t plen) { sop->aead.data.offset = sa->ctp.cipher.offset + pofs; sop->aead.data.length = sa->ctp.cipher.length + plen; sop->aead.digest.data = icv->va; sop->aead.digest.phys_addr = icv->pa; sop->aead.aad.data = icv->va + sa->icv_len; sop->aead.aad.phys_addr = icv->pa + sa->icv_len; } /* * setup crypto op and crypto sym op for ESP outbound packet. */ static inline void outb_cop_prepare(struct rte_crypto_op *cop, const struct rte_ipsec_sa *sa, const uint64_t ivp[IPSEC_MAX_IV_QWORD], const union sym_op_data *icv, uint32_t hlen, uint32_t plen) { struct rte_crypto_sym_op *sop; struct aead_gcm_iv *gcm; struct aead_ccm_iv *ccm; struct aead_chacha20_poly1305_iv *chacha20_poly1305; struct aesctr_cnt_blk *ctr; uint32_t algo; algo = sa->algo_type; /* fill sym op fields */ sop = cop->sym; switch (algo) { case ALGO_TYPE_AES_CBC: /* Cipher-Auth (AES-CBC *) case */ case ALGO_TYPE_3DES_CBC: /* Cipher-Auth (3DES-CBC *) case */ case ALGO_TYPE_NULL: /* NULL case */ sop_ciph_auth_prepare(sop, sa, icv, hlen, plen); break; case ALGO_TYPE_AES_GMAC: /* GMAC case */ sop_ciph_auth_prepare(sop, sa, icv, hlen, plen); /* fill AAD IV (located inside crypto op) */ gcm = rte_crypto_op_ctod_offset(cop, struct aead_gcm_iv *, sa->iv_ofs); aead_gcm_iv_fill(gcm, ivp[0], sa->salt); break; case ALGO_TYPE_AES_GCM: /* AEAD (AES_GCM) case */ sop_aead_prepare(sop, sa, icv, hlen, plen); /* fill AAD IV (located inside crypto op) */ gcm = rte_crypto_op_ctod_offset(cop, struct aead_gcm_iv *, sa->iv_ofs); aead_gcm_iv_fill(gcm, ivp[0], sa->salt); break; case ALGO_TYPE_AES_CCM: /* AEAD (AES_CCM) case */ sop_aead_prepare(sop, sa, icv, hlen, plen); /* fill AAD IV (located inside crypto op) */ ccm = rte_crypto_op_ctod_offset(cop, struct aead_ccm_iv *, sa->iv_ofs); aead_ccm_iv_fill(ccm, ivp[0], sa->salt); break; case ALGO_TYPE_CHACHA20_POLY1305: /* AEAD (CHACHA20_POLY) case */ sop_aead_prepare(sop, sa, icv, hlen, plen); /* fill AAD IV (located inside crypto op) */ chacha20_poly1305 = rte_crypto_op_ctod_offset(cop, struct aead_chacha20_poly1305_iv *, sa->iv_ofs); aead_chacha20_poly1305_iv_fill(chacha20_poly1305, ivp[0], sa->salt); break; case ALGO_TYPE_AES_CTR: /* Cipher-Auth (AES-CTR *) case */ sop_ciph_auth_prepare(sop, sa, icv, hlen, plen); /* fill CTR block (located inside crypto op) */ ctr = rte_crypto_op_ctod_offset(cop, struct aesctr_cnt_blk *, sa->iv_ofs); aes_ctr_cnt_blk_fill(ctr, ivp[0], sa->salt); break; } } /* * setup/update packet data and metadata for ESP outbound tunnel case. */ static inline int32_t outb_tun_pkt_prepare(struct rte_ipsec_sa *sa, rte_be64_t sqc, const uint64_t ivp[IPSEC_MAX_IV_QWORD], struct rte_mbuf *mb, union sym_op_data *icv, uint8_t sqh_len, uint8_t tso) { uint32_t clen, hlen, l2len, pdlen, pdofs, plen, tlen; struct rte_mbuf *ml; struct rte_esp_hdr *esph; struct rte_esp_tail *espt; char *ph, *pt; uint64_t *iv; /* calculate extra header space required */ hlen = sa->hdr_len + sa->iv_len + sizeof(*esph); /* size of ipsec protected data */ l2len = mb->l2_len; plen = mb->pkt_len - l2len; /* number of bytes to encrypt */ clen = plen + sizeof(*espt); if (!tso) { clen = RTE_ALIGN_CEIL(clen, sa->pad_align); /* pad length + esp tail */ pdlen = clen - plen; tlen = pdlen + sa->icv_len + sqh_len; } else { /* We don't need to pad/align packet or append ICV length * when using TSO offload */ pdlen = clen - plen; tlen = pdlen + sqh_len; } /* do append and prepend */ ml = rte_pktmbuf_lastseg(mb); if (tlen + sa->aad_len > rte_pktmbuf_tailroom(ml)) return -ENOSPC; /* prepend header */ ph = rte_pktmbuf_prepend(mb, hlen - l2len); if (ph == NULL) return -ENOSPC; /* append tail */ pdofs = ml->data_len; ml->data_len += tlen; mb->pkt_len += tlen; pt = rte_pktmbuf_mtod_offset(ml, typeof(pt), pdofs); /* update pkt l2/l3 len */ mb->tx_offload = (mb->tx_offload & sa->tx_offload.msk) | sa->tx_offload.val; /* copy tunnel pkt header */ rte_memcpy(ph, sa->hdr, sa->hdr_len); /* if UDP encap is enabled update the dgram_len */ if (sa->type & RTE_IPSEC_SATP_NATT_ENABLE) { struct rte_udp_hdr *udph = (struct rte_udp_hdr *) (ph + sa->hdr_len - sizeof(struct rte_udp_hdr)); udph->dgram_len = rte_cpu_to_be_16(mb->pkt_len - sqh_len - sa->hdr_len + sizeof(struct rte_udp_hdr)); } /* update original and new ip header fields */ update_tun_outb_l3hdr(sa, ph + sa->hdr_l3_off, ph + hlen, mb->pkt_len - sqh_len, sa->hdr_l3_off, sqn_low16(sqc)); /* update spi, seqn and iv */ esph = (struct rte_esp_hdr *)(ph + sa->hdr_len); iv = (uint64_t *)(esph + 1); copy_iv(iv, ivp, sa->iv_len); esph->spi = sa->spi; esph->seq = sqn_low32(sqc); /* offset for ICV */ pdofs += pdlen + sa->sqh_len; /* pad length */ pdlen -= sizeof(*espt); RTE_ASSERT(pdlen <= sizeof(esp_pad_bytes)); /* copy padding data */ rte_memcpy(pt, esp_pad_bytes, RTE_MIN(pdlen, sizeof(esp_pad_bytes))); /* update esp trailer */ espt = (struct rte_esp_tail *)(pt + pdlen); espt->pad_len = pdlen; espt->next_proto = sa->proto; /* set icv va/pa value(s) */ icv->va = rte_pktmbuf_mtod_offset(ml, void *, pdofs); icv->pa = rte_pktmbuf_iova_offset(ml, pdofs); return clen; } /* * for pure cryptodev (lookaside none) depending on SA settings, * we might have to write some extra data to the packet. */ static inline void outb_pkt_xprepare(const struct rte_ipsec_sa *sa, rte_be64_t sqc, const union sym_op_data *icv) { uint32_t *psqh; struct aead_gcm_aad *gaad; struct aead_ccm_aad *caad; struct aead_chacha20_poly1305_aad *chacha20_poly1305_aad; /* insert SQN.hi between ESP trailer and ICV */ if (sa->sqh_len != 0) { psqh = (uint32_t *)(icv->va - sa->sqh_len); psqh[0] = sqn_hi32(sqc); } /* * fill IV and AAD fields, if any (aad fields are placed after icv), * right now we support only one AEAD algorithm: AES-GCM . */ switch (sa->algo_type) { case ALGO_TYPE_AES_GCM: if (sa->aad_len != 0) { gaad = (struct aead_gcm_aad *)(icv->va + sa->icv_len); aead_gcm_aad_fill(gaad, sa->spi, sqc, IS_ESN(sa)); } break; case ALGO_TYPE_AES_CCM: if (sa->aad_len != 0) { caad = (struct aead_ccm_aad *)(icv->va + sa->icv_len); aead_ccm_aad_fill(caad, sa->spi, sqc, IS_ESN(sa)); } break; case ALGO_TYPE_CHACHA20_POLY1305: if (sa->aad_len != 0) { chacha20_poly1305_aad = (struct aead_chacha20_poly1305_aad *) (icv->va + sa->icv_len); aead_chacha20_poly1305_aad_fill(chacha20_poly1305_aad, sa->spi, sqc, IS_ESN(sa)); } break; default: break; } } /* * setup/update packets and crypto ops for ESP outbound tunnel case. */ uint16_t esp_outb_tun_prepare(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], struct rte_crypto_op *cop[], uint16_t num) { int32_t rc; uint32_t i, k, n; uint64_t sqn; rte_be64_t sqc; struct rte_ipsec_sa *sa; struct rte_cryptodev_sym_session *cs; union sym_op_data icv; uint64_t iv[IPSEC_MAX_IV_QWORD]; uint32_t dr[num]; sa = ss->sa; cs = ss->crypto.ses; n = num; sqn = esn_outb_update_sqn(sa, &n); if (n != num) rte_errno = EOVERFLOW; k = 0; for (i = 0; i != n; i++) { sqc = rte_cpu_to_be_64(sqn + i); gen_iv(iv, sqc); /* try to update the packet itself */ rc = outb_tun_pkt_prepare(sa, sqc, iv, mb[i], &icv, sa->sqh_len, 0); /* success, setup crypto op */ if (rc >= 0) { outb_pkt_xprepare(sa, sqc, &icv); lksd_none_cop_prepare(cop[k], cs, mb[i]); outb_cop_prepare(cop[k], sa, iv, &icv, 0, rc); k++; /* failure, put packet into the death-row */ } else { dr[i - k] = i; rte_errno = -rc; } } /* copy not prepared mbufs beyond good ones */ if (k != n && k != 0) move_bad_mbufs(mb, dr, n, n - k); return k; } /* * setup/update packet data and metadata for ESP outbound transport case. */ static inline int32_t outb_trs_pkt_prepare(struct rte_ipsec_sa *sa, rte_be64_t sqc, const uint64_t ivp[IPSEC_MAX_IV_QWORD], struct rte_mbuf *mb, union sym_op_data *icv, uint8_t sqh_len, uint8_t tso) { uint8_t np; uint32_t clen, hlen, pdlen, pdofs, plen, tlen, uhlen; struct rte_mbuf *ml; struct rte_esp_hdr *esph; struct rte_esp_tail *espt; char *ph, *pt; uint64_t *iv; uint32_t l2len, l3len; l2len = mb->l2_len; l3len = mb->l3_len; uhlen = l2len + l3len; plen = mb->pkt_len - uhlen; /* calculate extra header space required */ hlen = sa->iv_len + sizeof(*esph); /* number of bytes to encrypt */ clen = plen + sizeof(*espt); if (!tso) { clen = RTE_ALIGN_CEIL(clen, sa->pad_align); /* pad length + esp tail */ pdlen = clen - plen; tlen = pdlen + sa->icv_len + sqh_len; } else { /* We don't need to pad/align packet or append ICV length * when using TSO offload */ pdlen = clen - plen; tlen = pdlen + sqh_len; } /* do append and insert */ ml = rte_pktmbuf_lastseg(mb); if (tlen + sa->aad_len > rte_pktmbuf_tailroom(ml)) return -ENOSPC; /* prepend space for ESP header */ ph = rte_pktmbuf_prepend(mb, hlen); if (ph == NULL) return -ENOSPC; /* append tail */ pdofs = ml->data_len; ml->data_len += tlen; mb->pkt_len += tlen; pt = rte_pktmbuf_mtod_offset(ml, typeof(pt), pdofs); /* shift L2/L3 headers */ insert_esph(ph, ph + hlen, uhlen); /* update ip header fields */ np = update_trs_l3hdr(sa, ph + l2len, mb->pkt_len - sqh_len, l2len, l3len, IPPROTO_ESP); /* update spi, seqn and iv */ esph = (struct rte_esp_hdr *)(ph + uhlen); iv = (uint64_t *)(esph + 1); copy_iv(iv, ivp, sa->iv_len); esph->spi = sa->spi; esph->seq = sqn_low32(sqc); /* offset for ICV */ pdofs += pdlen + sa->sqh_len; /* pad length */ pdlen -= sizeof(*espt); RTE_ASSERT(pdlen <= sizeof(esp_pad_bytes)); /* copy padding data */ rte_memcpy(pt, esp_pad_bytes, RTE_MIN(pdlen, sizeof(esp_pad_bytes))); /* update esp trailer */ espt = (struct rte_esp_tail *)(pt + pdlen); espt->pad_len = pdlen; espt->next_proto = np; /* set icv va/pa value(s) */ icv->va = rte_pktmbuf_mtod_offset(ml, void *, pdofs); icv->pa = rte_pktmbuf_iova_offset(ml, pdofs); return clen; } /* * setup/update packets and crypto ops for ESP outbound transport case. */ uint16_t esp_outb_trs_prepare(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], struct rte_crypto_op *cop[], uint16_t num) { int32_t rc; uint32_t i, k, n, l2, l3; uint64_t sqn; rte_be64_t sqc; struct rte_ipsec_sa *sa; struct rte_cryptodev_sym_session *cs; union sym_op_data icv; uint64_t iv[IPSEC_MAX_IV_QWORD]; uint32_t dr[num]; sa = ss->sa; cs = ss->crypto.ses; n = num; sqn = esn_outb_update_sqn(sa, &n); if (n != num) rte_errno = EOVERFLOW; k = 0; for (i = 0; i != n; i++) { l2 = mb[i]->l2_len; l3 = mb[i]->l3_len; sqc = rte_cpu_to_be_64(sqn + i); gen_iv(iv, sqc); /* try to update the packet itself */ rc = outb_trs_pkt_prepare(sa, sqc, iv, mb[i], &icv, sa->sqh_len, 0); /* success, setup crypto op */ if (rc >= 0) { outb_pkt_xprepare(sa, sqc, &icv); lksd_none_cop_prepare(cop[k], cs, mb[i]); outb_cop_prepare(cop[k], sa, iv, &icv, l2 + l3, rc); k++; /* failure, put packet into the death-row */ } else { dr[i - k] = i; rte_errno = -rc; } } /* copy not prepared mbufs beyond good ones */ if (k != n && k != 0) move_bad_mbufs(mb, dr, n, n - k); return k; } static inline uint32_t outb_cpu_crypto_prepare(const struct rte_ipsec_sa *sa, uint32_t *pofs, uint32_t plen, void *iv) { uint64_t *ivp = iv; struct aead_gcm_iv *gcm; struct aead_ccm_iv *ccm; struct aead_chacha20_poly1305_iv *chacha20_poly1305; struct aesctr_cnt_blk *ctr; uint32_t clen; switch (sa->algo_type) { case ALGO_TYPE_AES_GCM: gcm = iv; aead_gcm_iv_fill(gcm, ivp[0], sa->salt); break; case ALGO_TYPE_AES_CCM: ccm = iv; aead_ccm_iv_fill(ccm, ivp[0], sa->salt); break; case ALGO_TYPE_CHACHA20_POLY1305: chacha20_poly1305 = iv; aead_chacha20_poly1305_iv_fill(chacha20_poly1305, ivp[0], sa->salt); break; case ALGO_TYPE_AES_CTR: ctr = iv; aes_ctr_cnt_blk_fill(ctr, ivp[0], sa->salt); break; } *pofs += sa->ctp.auth.offset; clen = plen + sa->ctp.auth.length; return clen; } static uint16_t cpu_outb_pkt_prepare(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num, esp_outb_prepare_t prepare, uint32_t cofs_mask) { int32_t rc; uint64_t sqn; rte_be64_t sqc; struct rte_ipsec_sa *sa; uint32_t i, k, n; uint32_t l2, l3; union sym_op_data icv; struct rte_crypto_va_iova_ptr iv[num]; struct rte_crypto_va_iova_ptr aad[num]; struct rte_crypto_va_iova_ptr dgst[num]; uint32_t dr[num]; uint32_t l4ofs[num]; uint32_t clen[num]; uint64_t ivbuf[num][IPSEC_MAX_IV_QWORD]; sa = ss->sa; n = num; sqn = esn_outb_update_sqn(sa, &n); if (n != num) rte_errno = EOVERFLOW; for (i = 0, k = 0; i != n; i++) { l2 = mb[i]->l2_len; l3 = mb[i]->l3_len; /* calculate ESP header offset */ l4ofs[k] = (l2 + l3) & cofs_mask; sqc = rte_cpu_to_be_64(sqn + i); gen_iv(ivbuf[k], sqc); /* try to update the packet itself */ rc = prepare(sa, sqc, ivbuf[k], mb[i], &icv, sa->sqh_len, 0); /* success, proceed with preparations */ if (rc >= 0) { outb_pkt_xprepare(sa, sqc, &icv); /* get encrypted data offset and length */ clen[k] = outb_cpu_crypto_prepare(sa, l4ofs + k, rc, ivbuf[k]); /* fill iv, digest and aad */ iv[k].va = ivbuf[k]; aad[k].va = icv.va + sa->icv_len; dgst[k++].va = icv.va; } else { dr[i - k] = i; rte_errno = -rc; } } /* copy not prepared mbufs beyond good ones */ if (k != n && k != 0) move_bad_mbufs(mb, dr, n, n - k); /* convert mbufs to iovecs and do actual crypto/auth processing */ if (k != 0) cpu_crypto_bulk(ss, sa->cofs, mb, iv, aad, dgst, l4ofs, clen, k); return k; } uint16_t cpu_outb_tun_pkt_prepare(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num) { return cpu_outb_pkt_prepare(ss, mb, num, outb_tun_pkt_prepare, 0); } uint16_t cpu_outb_trs_pkt_prepare(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num) { return cpu_outb_pkt_prepare(ss, mb, num, outb_trs_pkt_prepare, UINT32_MAX); } /* * process outbound packets for SA with ESN support, * for algorithms that require SQN.hibits to be implicitly included * into digest computation. * In that case we have to move ICV bytes back to their proper place. */ uint16_t esp_outb_sqh_process(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num) { uint32_t i, k, icv_len, *icv, bytes; struct rte_mbuf *ml; struct rte_ipsec_sa *sa; uint32_t dr[num]; sa = ss->sa; k = 0; icv_len = sa->icv_len; bytes = 0; for (i = 0; i != num; i++) { if ((mb[i]->ol_flags & RTE_MBUF_F_RX_SEC_OFFLOAD_FAILED) == 0) { ml = rte_pktmbuf_lastseg(mb[i]); /* remove high-order 32 bits of esn from packet len */ mb[i]->pkt_len -= sa->sqh_len; ml->data_len -= sa->sqh_len; icv = rte_pktmbuf_mtod_offset(ml, void *, ml->data_len - icv_len); remove_sqh(icv, icv_len); bytes += mb[i]->pkt_len; k++; } else dr[i - k] = i; } sa->statistics.count += k; sa->statistics.bytes += bytes; /* handle unprocessed mbufs */ if (k != num) { rte_errno = EBADMSG; if (k != 0) move_bad_mbufs(mb, dr, num, num - k); } return k; } /* * prepare packets for inline ipsec processing: * set ol_flags and attach metadata. */ static inline void inline_outb_mbuf_prepare(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num) { uint32_t i, ol_flags, bytes; ol_flags = ss->security.ol_flags & RTE_SECURITY_TX_OLOAD_NEED_MDATA; bytes = 0; for (i = 0; i != num; i++) { mb[i]->ol_flags |= RTE_MBUF_F_TX_SEC_OFFLOAD; bytes += mb[i]->pkt_len; if (ol_flags != 0) rte_security_set_pkt_metadata(ss->security.ctx, ss->security.ses, mb[i], NULL); } ss->sa->statistics.count += num; ss->sa->statistics.bytes += bytes; } static inline int esn_outb_nb_segments(struct rte_mbuf *m) { if (m->ol_flags & (RTE_MBUF_F_TX_TCP_SEG | RTE_MBUF_F_TX_UDP_SEG)) { uint16_t pkt_l3len = m->pkt_len - m->l2_len; uint16_t segments = (m->tso_segsz > 0 && pkt_l3len > m->tso_segsz) ? (pkt_l3len + m->tso_segsz - 1) / m->tso_segsz : 1; return segments; } return 1; /* no TSO */ } /* Compute how many packets can be sent before overflow occurs */ static inline uint16_t esn_outb_nb_valid_packets(uint16_t num, uint32_t n_sqn, uint16_t nb_segs[]) { uint16_t i; uint32_t seg_cnt = 0; for (i = 0; i < num && seg_cnt < n_sqn; i++) seg_cnt += nb_segs[i]; return i - 1; } /* * process group of ESP outbound tunnel packets destined for * INLINE_CRYPTO type of device. */ uint16_t inline_outb_tun_pkt_process(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num) { int32_t rc; uint32_t i, k, nb_segs_total, n_sqn; uint64_t sqn; rte_be64_t sqc; struct rte_ipsec_sa *sa; union sym_op_data icv; uint64_t iv[IPSEC_MAX_IV_QWORD]; uint32_t dr[num]; uint16_t nb_segs[num]; sa = ss->sa; nb_segs_total = 0; /* Calculate number of segments */ for (i = 0; i != num; i++) { nb_segs[i] = esn_outb_nb_segments(mb[i]); nb_segs_total += nb_segs[i]; } n_sqn = nb_segs_total; sqn = esn_outb_update_sqn(sa, &n_sqn); if (n_sqn != nb_segs_total) { rte_errno = EOVERFLOW; /* if there are segmented packets find out how many can be * sent until overflow occurs */ if (nb_segs_total > num) /* there is at least 1 */ num = esn_outb_nb_valid_packets(num, n_sqn, nb_segs); else num = n_sqn; /* no segmented packets */ } k = 0; for (i = 0; i != num; i++) { sqc = rte_cpu_to_be_64(sqn); gen_iv(iv, sqc); sqn += nb_segs[i]; /* try to update the packet itself */ rc = outb_tun_pkt_prepare(sa, sqc, iv, mb[i], &icv, 0, (mb[i]->ol_flags & (RTE_MBUF_F_TX_TCP_SEG | RTE_MBUF_F_TX_UDP_SEG)) != 0); k += (rc >= 0); /* failure, put packet into the death-row */ if (rc < 0) { dr[i - k] = i; rte_errno = -rc; } } /* copy not processed mbufs beyond good ones */ if (k != num && k != 0) move_bad_mbufs(mb, dr, num, num - k); inline_outb_mbuf_prepare(ss, mb, k); return k; } /* * process group of ESP outbound transport packets destined for * INLINE_CRYPTO type of device. */ uint16_t inline_outb_trs_pkt_process(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num) { int32_t rc; uint32_t i, k, nb_segs_total, n_sqn; uint64_t sqn; rte_be64_t sqc; struct rte_ipsec_sa *sa; union sym_op_data icv; uint64_t iv[IPSEC_MAX_IV_QWORD]; uint32_t dr[num]; uint16_t nb_segs[num]; sa = ss->sa; nb_segs_total = 0; /* Calculate number of segments */ for (i = 0; i != num; i++) { nb_segs[i] = esn_outb_nb_segments(mb[i]); nb_segs_total += nb_segs[i]; } n_sqn = nb_segs_total; sqn = esn_outb_update_sqn(sa, &n_sqn); if (n_sqn != nb_segs_total) { rte_errno = EOVERFLOW; /* if there are segmented packets find out how many can be * sent until overflow occurs */ if (nb_segs_total > num) /* there is at least 1 */ num = esn_outb_nb_valid_packets(num, n_sqn, nb_segs); else num = n_sqn; /* no segmented packets */ } k = 0; for (i = 0; i != num; i++) { sqc = rte_cpu_to_be_64(sqn); gen_iv(iv, sqc); sqn += nb_segs[i]; /* try to update the packet itself */ rc = outb_trs_pkt_prepare(sa, sqc, iv, mb[i], &icv, 0, (mb[i]->ol_flags & (RTE_MBUF_F_TX_TCP_SEG | RTE_MBUF_F_TX_UDP_SEG)) != 0); k += (rc >= 0); /* failure, put packet into the death-row */ if (rc < 0) { dr[i - k] = i; rte_errno = -rc; } } /* copy not processed mbufs beyond good ones */ if (k != num && k != 0) move_bad_mbufs(mb, dr, num, num - k); inline_outb_mbuf_prepare(ss, mb, k); return k; } /* * outbound for RTE_SECURITY_ACTION_TYPE_INLINE_PROTOCOL: * actual processing is done by HW/PMD, just set flags and metadata. */ uint16_t inline_proto_outb_pkt_process(const struct rte_ipsec_session *ss, struct rte_mbuf *mb[], uint16_t num) { inline_outb_mbuf_prepare(ss, mb, num); return num; }