/* SPDX-License-Identifier: BSD-3-Clause * * Copyright(c) 2019-2021 Xilinx, Inc. * Copyright(c) 2018-2019 Solarflare Communications Inc. * * This software was jointly developed between OKTET Labs (under contract * for Solarflare) and Solarflare Communications, Inc. */ #include #include #include #include #include #include "efx.h" #include "efx_types.h" #include "efx_regs.h" #include "efx_regs_ef100.h" #include "sfc_debug.h" #include "sfc_dp_tx.h" #include "sfc_tweak.h" #include "sfc_kvargs.h" #include "sfc_ef100.h" #include "sfc_nic_dma_dp.h" #define sfc_ef100_tx_err(_txq, ...) \ SFC_DP_LOG(SFC_KVARG_DATAPATH_EF100, ERR, &(_txq)->dp.dpq, __VA_ARGS__) #define sfc_ef100_tx_debug(_txq, ...) \ SFC_DP_LOG(SFC_KVARG_DATAPATH_EF100, DEBUG, &(_txq)->dp.dpq, \ __VA_ARGS__) /** Maximum length of the send descriptor data */ #define SFC_EF100_TX_SEND_DESC_LEN_MAX \ ((1u << ESF_GZ_TX_SEND_LEN_WIDTH) - 1) /** Maximum length of the segment descriptor data */ #define SFC_EF100_TX_SEG_DESC_LEN_MAX \ ((1u << ESF_GZ_TX_SEG_LEN_WIDTH) - 1) /** * Maximum number of descriptors/buffers in the Tx ring. * It should guarantee that corresponding event queue never overfill. * EF100 native datapath uses event queue of the same size as Tx queue. * Maximum number of events on datapath can be estimated as number of * Tx queue entries (one event per Tx buffer in the worst case) plus * Tx error and flush events. */ #define SFC_EF100_TXQ_LIMIT(_ndesc) \ ((_ndesc) - 1 /* head must not step on tail */ - \ 1 /* Rx error */ - 1 /* flush */) struct sfc_ef100_tx_sw_desc { struct rte_mbuf *mbuf; }; struct sfc_ef100_txq { unsigned int flags; #define SFC_EF100_TXQ_STARTED 0x1 #define SFC_EF100_TXQ_NOT_RUNNING 0x2 #define SFC_EF100_TXQ_EXCEPTION 0x4 #define SFC_EF100_TXQ_NIC_DMA_MAP 0x8 unsigned int ptr_mask; unsigned int added; unsigned int completed; unsigned int max_fill_level; unsigned int free_thresh; struct sfc_ef100_tx_sw_desc *sw_ring; efx_oword_t *txq_hw_ring; volatile void *doorbell; /* Completion/reap */ unsigned int evq_read_ptr; unsigned int evq_phase_bit_shift; volatile efx_qword_t *evq_hw_ring; uint16_t tso_tcp_header_offset_limit; uint16_t tso_max_nb_header_descs; uint16_t tso_max_header_len; uint16_t tso_max_nb_payload_descs; uint32_t tso_max_payload_len; uint32_t tso_max_nb_outgoing_frames; /* Datapath transmit queue anchor */ struct sfc_dp_txq dp; const struct sfc_nic_dma_info *nic_dma_info; }; static inline struct sfc_ef100_txq * sfc_ef100_txq_by_dp_txq(struct sfc_dp_txq *dp_txq) { return container_of(dp_txq, struct sfc_ef100_txq, dp); } static int sfc_ef100_tx_prepare_pkt_tso(struct sfc_ef100_txq * const txq, struct rte_mbuf *m) { size_t header_len = ((m->ol_flags & RTE_MBUF_F_TX_TUNNEL_MASK) ? m->outer_l2_len + m->outer_l3_len : 0) + m->l2_len + m->l3_len + m->l4_len; size_t payload_len = m->pkt_len - header_len; unsigned long mss_conformant_max_payload_len; unsigned int nb_payload_descs; #ifdef RTE_LIBRTE_SFC_EFX_DEBUG switch (m->ol_flags & RTE_MBUF_F_TX_TUNNEL_MASK) { case 0: /* FALLTHROUGH */ case RTE_MBUF_F_TX_TUNNEL_VXLAN: /* FALLTHROUGH */ case RTE_MBUF_F_TX_TUNNEL_GENEVE: break; default: return ENOTSUP; } #endif mss_conformant_max_payload_len = m->tso_segsz * txq->tso_max_nb_outgoing_frames; /* * Don't really want to know exact number of payload segments. * Just use total number of segments as upper limit. Practically * maximum number of payload segments is significantly bigger * than maximum number header segments, so we can neglect header * segments excluded total number of segments to estimate number * of payload segments required. */ nb_payload_descs = m->nb_segs; /* * Carry out multiple independent checks using bitwise OR * to avoid unnecessary conditional branching. */ if (unlikely((header_len > txq->tso_max_header_len) | (nb_payload_descs > txq->tso_max_nb_payload_descs) | (payload_len > txq->tso_max_payload_len) | (payload_len > mss_conformant_max_payload_len) | (m->pkt_len == header_len))) return EINVAL; return 0; } static uint16_t sfc_ef100_tx_prepare_pkts(void *tx_queue, struct rte_mbuf **tx_pkts, uint16_t nb_pkts) { struct sfc_ef100_txq * const txq = sfc_ef100_txq_by_dp_txq(tx_queue); uint16_t i; for (i = 0; i < nb_pkts; i++) { struct rte_mbuf *m = tx_pkts[i]; unsigned int max_nb_header_segs = 0; bool calc_phdr_cksum = false; int ret; /* * Partial checksum offload is used in the case of * inner TCP/UDP checksum offload. It requires * pseudo-header checksum which is calculated below, * but requires contiguous packet headers. */ if ((m->ol_flags & RTE_MBUF_F_TX_TUNNEL_MASK) && (m->ol_flags & RTE_MBUF_F_TX_L4_MASK)) { calc_phdr_cksum = true; max_nb_header_segs = 1; } else if (m->ol_flags & RTE_MBUF_F_TX_TCP_SEG) { max_nb_header_segs = txq->tso_max_nb_header_descs; } ret = sfc_dp_tx_prepare_pkt(m, max_nb_header_segs, 0, txq->tso_tcp_header_offset_limit, txq->max_fill_level, 1, 0); if (unlikely(ret != 0)) { rte_errno = ret; break; } if (m->ol_flags & RTE_MBUF_F_TX_TCP_SEG) { ret = sfc_ef100_tx_prepare_pkt_tso(txq, m); if (unlikely(ret != 0)) { rte_errno = ret; break; } } else if (m->nb_segs > EFX_MASK32(ESF_GZ_TX_SEND_NUM_SEGS)) { rte_errno = EINVAL; break; } if (calc_phdr_cksum) { /* * Full checksum offload does IPv4 header checksum * and does not require any assistance. */ ret = rte_net_intel_cksum_flags_prepare(m, m->ol_flags & ~RTE_MBUF_F_TX_IP_CKSUM); if (unlikely(ret != 0)) { rte_errno = -ret; break; } } } return i; } static bool sfc_ef100_tx_get_event(struct sfc_ef100_txq *txq, efx_qword_t *ev) { volatile efx_qword_t *evq_hw_ring = txq->evq_hw_ring; /* * Exception flag is set when reap is done. * It is never done twice per packet burst get, and absence of * the flag is checked on burst get entry. */ SFC_ASSERT((txq->flags & SFC_EF100_TXQ_EXCEPTION) == 0); *ev = evq_hw_ring[txq->evq_read_ptr & txq->ptr_mask]; if (!sfc_ef100_ev_present(ev, (txq->evq_read_ptr >> txq->evq_phase_bit_shift) & 1)) return false; if (unlikely(!sfc_ef100_ev_type_is(ev, ESE_GZ_EF100_EV_TX_COMPLETION))) { /* * Do not move read_ptr to keep the event for exception * handling by the control path. */ txq->flags |= SFC_EF100_TXQ_EXCEPTION; sfc_ef100_tx_err(txq, "TxQ exception at EvQ ptr %u(%#x), event %08x:%08x", txq->evq_read_ptr, txq->evq_read_ptr & txq->ptr_mask, EFX_QWORD_FIELD(*ev, EFX_DWORD_1), EFX_QWORD_FIELD(*ev, EFX_DWORD_0)); return false; } sfc_ef100_tx_debug(txq, "TxQ got event %08x:%08x at %u (%#x)", EFX_QWORD_FIELD(*ev, EFX_DWORD_1), EFX_QWORD_FIELD(*ev, EFX_DWORD_0), txq->evq_read_ptr, txq->evq_read_ptr & txq->ptr_mask); txq->evq_read_ptr++; return true; } static unsigned int sfc_ef100_tx_process_events(struct sfc_ef100_txq *txq) { unsigned int num_descs = 0; efx_qword_t tx_ev; while (sfc_ef100_tx_get_event(txq, &tx_ev)) num_descs += EFX_QWORD_FIELD(tx_ev, ESF_GZ_EV_TXCMPL_NUM_DESC); return num_descs; } static void sfc_ef100_tx_reap_num_descs(struct sfc_ef100_txq *txq, unsigned int num_descs) { if (num_descs > 0) { unsigned int completed = txq->completed; unsigned int pending = completed + num_descs; struct rte_mbuf *bulk[SFC_TX_REAP_BULK_SIZE]; unsigned int nb = 0; do { struct sfc_ef100_tx_sw_desc *txd; struct rte_mbuf *m; txd = &txq->sw_ring[completed & txq->ptr_mask]; if (txd->mbuf == NULL) continue; m = rte_pktmbuf_prefree_seg(txd->mbuf); if (m == NULL) continue; txd->mbuf = NULL; if (nb == RTE_DIM(bulk) || (nb != 0 && m->pool != bulk[0]->pool)) { rte_mempool_put_bulk(bulk[0]->pool, (void *)bulk, nb); nb = 0; } bulk[nb++] = m; } while (++completed != pending); if (nb != 0) rte_mempool_put_bulk(bulk[0]->pool, (void *)bulk, nb); txq->completed = completed; } } static void sfc_ef100_tx_reap(struct sfc_ef100_txq *txq) { sfc_ef100_tx_reap_num_descs(txq, sfc_ef100_tx_process_events(txq)); } static void sfc_ef100_tx_qdesc_prefix_create(const struct rte_mbuf *m, efx_oword_t *tx_desc) { efx_mport_id_t *mport_id = RTE_MBUF_DYNFIELD(m, sfc_dp_mport_offset, efx_mport_id_t *); EFX_POPULATE_OWORD_3(*tx_desc, ESF_GZ_TX_PREFIX_EGRESS_MPORT, mport_id->id, ESF_GZ_TX_PREFIX_EGRESS_MPORT_EN, 1, ESF_GZ_TX_DESC_TYPE, ESE_GZ_TX_DESC_TYPE_PREFIX); } static uint8_t sfc_ef100_tx_qdesc_cso_inner_l3(uint64_t tx_tunnel) { uint8_t inner_l3; switch (tx_tunnel) { case RTE_MBUF_F_TX_TUNNEL_VXLAN: inner_l3 = ESE_GZ_TX_DESC_CS_INNER_L3_VXLAN; break; case RTE_MBUF_F_TX_TUNNEL_GENEVE: inner_l3 = ESE_GZ_TX_DESC_CS_INNER_L3_GENEVE; break; default: inner_l3 = ESE_GZ_TX_DESC_CS_INNER_L3_OFF; break; } return inner_l3; } static int sfc_ef100_tx_map(const struct sfc_ef100_txq *txq, rte_iova_t iova, size_t len, rte_iova_t *dma_addr) { if ((txq->flags & SFC_EF100_TXQ_NIC_DMA_MAP) == 0) { *dma_addr = iova; } else { *dma_addr = sfc_nic_dma_map(txq->nic_dma_info, iova, len); if (unlikely(*dma_addr == RTE_BAD_IOVA)) sfc_ef100_tx_err(txq, "failed to map DMA address on Tx"); } return 0; } static int sfc_ef100_tx_qdesc_send_create(const struct sfc_ef100_txq *txq, const struct rte_mbuf *m, efx_oword_t *tx_desc) { bool outer_l3; bool outer_l4; uint8_t inner_l3; uint8_t partial_en; uint16_t part_cksum_w; uint16_t l4_offset_w; rte_iova_t dma_addr; int rc; if ((m->ol_flags & RTE_MBUF_F_TX_TUNNEL_MASK) == 0) { outer_l3 = (m->ol_flags & RTE_MBUF_F_TX_IP_CKSUM); outer_l4 = (m->ol_flags & RTE_MBUF_F_TX_L4_MASK); inner_l3 = ESE_GZ_TX_DESC_CS_INNER_L3_OFF; partial_en = ESE_GZ_TX_DESC_CSO_PARTIAL_EN_OFF; part_cksum_w = 0; l4_offset_w = 0; } else { outer_l3 = (m->ol_flags & RTE_MBUF_F_TX_OUTER_IP_CKSUM); outer_l4 = (m->ol_flags & RTE_MBUF_F_TX_OUTER_UDP_CKSUM); inner_l3 = sfc_ef100_tx_qdesc_cso_inner_l3(m->ol_flags & RTE_MBUF_F_TX_TUNNEL_MASK); switch (m->ol_flags & RTE_MBUF_F_TX_L4_MASK) { case RTE_MBUF_F_TX_TCP_CKSUM: partial_en = ESE_GZ_TX_DESC_CSO_PARTIAL_EN_TCP; part_cksum_w = offsetof(struct rte_tcp_hdr, cksum) >> 1; break; case RTE_MBUF_F_TX_UDP_CKSUM: partial_en = ESE_GZ_TX_DESC_CSO_PARTIAL_EN_UDP; part_cksum_w = offsetof(struct rte_udp_hdr, dgram_cksum) >> 1; break; default: partial_en = ESE_GZ_TX_DESC_CSO_PARTIAL_EN_OFF; part_cksum_w = 0; break; } l4_offset_w = (m->outer_l2_len + m->outer_l3_len + m->l2_len + m->l3_len) >> 1; } rc = sfc_ef100_tx_map(txq, rte_mbuf_data_iova_default(m), rte_pktmbuf_data_len(m), &dma_addr); if (unlikely(rc != 0)) return rc; EFX_POPULATE_OWORD_10(*tx_desc, ESF_GZ_TX_SEND_ADDR, dma_addr, ESF_GZ_TX_SEND_LEN, rte_pktmbuf_data_len(m), ESF_GZ_TX_SEND_NUM_SEGS, m->nb_segs, ESF_GZ_TX_SEND_CSO_PARTIAL_START_W, l4_offset_w, ESF_GZ_TX_SEND_CSO_PARTIAL_CSUM_W, part_cksum_w, ESF_GZ_TX_SEND_CSO_PARTIAL_EN, partial_en, ESF_GZ_TX_SEND_CSO_INNER_L3, inner_l3, ESF_GZ_TX_SEND_CSO_OUTER_L3, outer_l3, ESF_GZ_TX_SEND_CSO_OUTER_L4, outer_l4, ESF_GZ_TX_DESC_TYPE, ESE_GZ_TX_DESC_TYPE_SEND); if (m->ol_flags & RTE_MBUF_F_TX_VLAN) { efx_oword_t tx_desc_extra_fields; EFX_POPULATE_OWORD_2(tx_desc_extra_fields, ESF_GZ_TX_SEND_VLAN_INSERT_EN, 1, ESF_GZ_TX_SEND_VLAN_INSERT_TCI, m->vlan_tci); EFX_OR_OWORD(*tx_desc, tx_desc_extra_fields); } return 0; } static void sfc_ef100_tx_qdesc_seg_create(rte_iova_t addr, uint16_t len, efx_oword_t *tx_desc) { EFX_POPULATE_OWORD_3(*tx_desc, ESF_GZ_TX_SEG_ADDR, addr, ESF_GZ_TX_SEG_LEN, len, ESF_GZ_TX_DESC_TYPE, ESE_GZ_TX_DESC_TYPE_SEG); } static void sfc_ef100_tx_qdesc_tso_create(const struct rte_mbuf *m, uint16_t nb_header_descs, uint16_t nb_payload_descs, size_t header_len, size_t payload_len, size_t outer_iph_off, size_t outer_udph_off, size_t iph_off, size_t tcph_off, efx_oword_t *tx_desc) { efx_oword_t tx_desc_extra_fields; int ed_outer_udp_len = (outer_udph_off != 0) ? 1 : 0; int ed_outer_ip_len = (outer_iph_off != 0) ? 1 : 0; int ed_outer_ip_id = (outer_iph_off != 0) ? ESE_GZ_TX_DESC_IP4_ID_INC_MOD16 : 0; /* * If no tunnel encapsulation is present, then the ED_INNER * fields should be used. */ int ed_inner_ip_id = ESE_GZ_TX_DESC_IP4_ID_INC_MOD16; uint8_t inner_l3 = sfc_ef100_tx_qdesc_cso_inner_l3( m->ol_flags & RTE_MBUF_F_TX_TUNNEL_MASK); EFX_POPULATE_OWORD_10(*tx_desc, ESF_GZ_TX_TSO_MSS, m->tso_segsz, ESF_GZ_TX_TSO_HDR_NUM_SEGS, nb_header_descs, ESF_GZ_TX_TSO_PAYLOAD_NUM_SEGS, nb_payload_descs, ESF_GZ_TX_TSO_ED_OUTER_IP4_ID, ed_outer_ip_id, ESF_GZ_TX_TSO_ED_INNER_IP4_ID, ed_inner_ip_id, ESF_GZ_TX_TSO_ED_OUTER_IP_LEN, ed_outer_ip_len, ESF_GZ_TX_TSO_ED_INNER_IP_LEN, 1, ESF_GZ_TX_TSO_ED_OUTER_UDP_LEN, ed_outer_udp_len, ESF_GZ_TX_TSO_HDR_LEN_W, header_len >> 1, ESF_GZ_TX_TSO_PAYLOAD_LEN, payload_len); EFX_POPULATE_OWORD_9(tx_desc_extra_fields, /* * Outer offsets are required for outer IPv4 ID * and length edits in the case of tunnel TSO. */ ESF_GZ_TX_TSO_OUTER_L3_OFF_W, outer_iph_off >> 1, ESF_GZ_TX_TSO_OUTER_L4_OFF_W, outer_udph_off >> 1, /* * Inner offsets are required for inner IPv4 ID * and IP length edits and partial checksum * offload in the case of tunnel TSO. */ ESF_GZ_TX_TSO_INNER_L3_OFF_W, iph_off >> 1, ESF_GZ_TX_TSO_INNER_L4_OFF_W, tcph_off >> 1, ESF_GZ_TX_TSO_CSO_INNER_L4, inner_l3 != ESE_GZ_TX_DESC_CS_INNER_L3_OFF, ESF_GZ_TX_TSO_CSO_INNER_L3, inner_l3, /* * Use outer full checksum offloads which do * not require any extra information. */ ESF_GZ_TX_TSO_CSO_OUTER_L3, 1, ESF_GZ_TX_TSO_CSO_OUTER_L4, 1, ESF_GZ_TX_DESC_TYPE, ESE_GZ_TX_DESC_TYPE_TSO); EFX_OR_OWORD(*tx_desc, tx_desc_extra_fields); if (m->ol_flags & RTE_MBUF_F_TX_VLAN) { EFX_POPULATE_OWORD_2(tx_desc_extra_fields, ESF_GZ_TX_TSO_VLAN_INSERT_EN, 1, ESF_GZ_TX_TSO_VLAN_INSERT_TCI, m->vlan_tci); EFX_OR_OWORD(*tx_desc, tx_desc_extra_fields); } } static inline void sfc_ef100_tx_qpush(struct sfc_ef100_txq *txq, unsigned int added) { efx_dword_t dword; EFX_POPULATE_DWORD_1(dword, ERF_GZ_TX_RING_PIDX, added & txq->ptr_mask); /* DMA sync to device is not required */ /* * rte_write32() has rte_io_wmb() which guarantees that the STORE * operations (i.e. Rx and event descriptor updates) that precede * the rte_io_wmb() call are visible to NIC before the STORE * operations that follow it (i.e. doorbell write). */ rte_write32(dword.ed_u32[0], txq->doorbell); txq->dp.dpq.dbells++; sfc_ef100_tx_debug(txq, "TxQ pushed doorbell at pidx %u (added=%u)", EFX_DWORD_FIELD(dword, ERF_GZ_TX_RING_PIDX), added); } static unsigned int sfc_ef100_tx_pkt_descs_max(const struct rte_mbuf *m) { unsigned int extra_descs = 0; /** Maximum length of an mbuf segment data */ #define SFC_MBUF_SEG_LEN_MAX UINT16_MAX RTE_BUILD_BUG_ON(sizeof(m->data_len) != 2); if (m->ol_flags & RTE_MBUF_F_TX_TCP_SEG) { /* Tx TSO descriptor */ extra_descs++; /* * Extra Tx segment descriptor may be required if header * ends in the middle of segment. */ extra_descs++; } else { /* * mbuf segment cannot be bigger than maximum segment length * and maximum packet length since TSO is not supported yet. * Make sure that the first segment does not need fragmentation * (split into many Tx descriptors). */ RTE_BUILD_BUG_ON(SFC_EF100_TX_SEND_DESC_LEN_MAX < RTE_MIN((unsigned int)EFX_MAC_PDU_MAX, SFC_MBUF_SEG_LEN_MAX)); } if (m->ol_flags & sfc_dp_mport_override) { /* Tx override prefix descriptor will be used */ extra_descs++; } /* * Any segment of scattered packet cannot be bigger than maximum * segment length. Make sure that subsequent segments do not need * fragmentation (split into many Tx descriptors). */ RTE_BUILD_BUG_ON(SFC_EF100_TX_SEG_DESC_LEN_MAX < SFC_MBUF_SEG_LEN_MAX); return m->nb_segs + extra_descs; } static int sfc_ef100_xmit_tso_pkt(struct sfc_ef100_txq * const txq, struct rte_mbuf **m, unsigned int *added) { struct rte_mbuf *m_seg = *m; unsigned int nb_hdr_descs; unsigned int nb_pld_descs; unsigned int seg_split = 0; unsigned int tso_desc_id; unsigned int id; size_t outer_iph_off; size_t outer_udph_off; size_t iph_off; size_t tcph_off; size_t header_len; size_t remaining_hdr_len; rte_iova_t dma_addr; int rc; if (m_seg->ol_flags & RTE_MBUF_F_TX_TUNNEL_MASK) { outer_iph_off = m_seg->outer_l2_len; outer_udph_off = outer_iph_off + m_seg->outer_l3_len; } else { outer_iph_off = 0; outer_udph_off = 0; } iph_off = outer_udph_off + m_seg->l2_len; tcph_off = iph_off + m_seg->l3_len; header_len = tcph_off + m_seg->l4_len; /* * Remember ID of the TX_TSO descriptor to be filled in. * We can't fill it in right now since we need to calculate * number of header and payload segments first and don't want * to traverse it twice here. */ tso_desc_id = (*added)++ & txq->ptr_mask; remaining_hdr_len = header_len; do { rc = sfc_ef100_tx_map(txq, rte_mbuf_data_iova(m_seg), rte_pktmbuf_data_len(m_seg), &dma_addr); if (unlikely(rc != 0)) return rc; id = (*added)++ & txq->ptr_mask; if (rte_pktmbuf_data_len(m_seg) <= remaining_hdr_len) { /* The segment is fully header segment */ sfc_ef100_tx_qdesc_seg_create(dma_addr, rte_pktmbuf_data_len(m_seg), &txq->txq_hw_ring[id]); remaining_hdr_len -= rte_pktmbuf_data_len(m_seg); } else { /* * The segment must be split into header and * payload segments */ sfc_ef100_tx_qdesc_seg_create(dma_addr, remaining_hdr_len, &txq->txq_hw_ring[id]); txq->sw_ring[id].mbuf = NULL; id = (*added)++ & txq->ptr_mask; sfc_ef100_tx_qdesc_seg_create( dma_addr + remaining_hdr_len, rte_pktmbuf_data_len(m_seg) - remaining_hdr_len, &txq->txq_hw_ring[id]); remaining_hdr_len = 0; seg_split = 1; } txq->sw_ring[id].mbuf = m_seg; m_seg = m_seg->next; } while (remaining_hdr_len > 0); /* * If a segment is split into header and payload segments, added * pointer counts it twice and we should correct it. */ nb_hdr_descs = ((id - tso_desc_id) & txq->ptr_mask) - seg_split; nb_pld_descs = (*m)->nb_segs - nb_hdr_descs + seg_split; sfc_ef100_tx_qdesc_tso_create(*m, nb_hdr_descs, nb_pld_descs, header_len, rte_pktmbuf_pkt_len(*m) - header_len, outer_iph_off, outer_udph_off, iph_off, tcph_off, &txq->txq_hw_ring[tso_desc_id]); *m = m_seg; return 0; } static uint16_t sfc_ef100_xmit_pkts(void *tx_queue, struct rte_mbuf **tx_pkts, uint16_t nb_pkts) { struct sfc_ef100_txq * const txq = sfc_ef100_txq_by_dp_txq(tx_queue); unsigned int added; unsigned int dma_desc_space; bool reap_done; struct rte_mbuf **pktp; struct rte_mbuf **pktp_end; rte_iova_t dma_addr; int rc; if (unlikely(txq->flags & (SFC_EF100_TXQ_NOT_RUNNING | SFC_EF100_TXQ_EXCEPTION))) return 0; added = txq->added; dma_desc_space = txq->max_fill_level - (added - txq->completed); reap_done = (dma_desc_space < txq->free_thresh); if (reap_done) { sfc_ef100_tx_reap(txq); dma_desc_space = txq->max_fill_level - (added - txq->completed); } for (pktp = &tx_pkts[0], pktp_end = &tx_pkts[nb_pkts]; pktp != pktp_end; ++pktp) { struct rte_mbuf *m_seg = *pktp; unsigned int pkt_start = added; unsigned int id; if (likely(pktp + 1 != pktp_end)) rte_mbuf_prefetch_part1(pktp[1]); if (sfc_ef100_tx_pkt_descs_max(m_seg) > dma_desc_space) { if (reap_done) break; /* Push already prepared descriptors before polling */ if (added != txq->added) { sfc_ef100_tx_qpush(txq, added); txq->added = added; } sfc_ef100_tx_reap(txq); reap_done = true; dma_desc_space = txq->max_fill_level - (added - txq->completed); if (sfc_ef100_tx_pkt_descs_max(m_seg) > dma_desc_space) break; } if (m_seg->ol_flags & sfc_dp_mport_override) { id = added++ & txq->ptr_mask; sfc_ef100_tx_qdesc_prefix_create(m_seg, &txq->txq_hw_ring[id]); txq->sw_ring[id].mbuf = NULL; } if (m_seg->ol_flags & RTE_MBUF_F_TX_TCP_SEG) { rc = sfc_ef100_xmit_tso_pkt(txq, &m_seg, &added); } else { id = added++ & txq->ptr_mask; rc = sfc_ef100_tx_qdesc_send_create(txq, m_seg, &txq->txq_hw_ring[id]); /* * rte_pktmbuf_free() is commonly used in DPDK for * recycling packets - the function checks every * segment's reference counter and returns the * buffer to its pool whenever possible; * nevertheless, freeing mbuf segments one by one * may entail some performance decline; * from this point, sfc_efx_tx_reap() does the same job * on its own and frees buffers in bulks (all mbufs * within a bulk belong to the same pool); * from this perspective, individual segment pointers * must be associated with the corresponding SW * descriptors independently so that only one loop * is sufficient on reap to inspect all the buffers */ txq->sw_ring[id].mbuf = m_seg; m_seg = m_seg->next; } while (likely(rc == 0) && m_seg != NULL) { RTE_BUILD_BUG_ON(SFC_MBUF_SEG_LEN_MAX > SFC_EF100_TX_SEG_DESC_LEN_MAX); id = added++ & txq->ptr_mask; rc = sfc_ef100_tx_map(txq, rte_mbuf_data_iova(m_seg), rte_pktmbuf_data_len(m_seg), &dma_addr); sfc_ef100_tx_qdesc_seg_create(dma_addr, rte_pktmbuf_data_len(m_seg), &txq->txq_hw_ring[id]); txq->sw_ring[id].mbuf = m_seg; m_seg = m_seg->next; } if (likely(rc == 0)) { dma_desc_space -= (added - pkt_start); sfc_pkts_bytes_add(&txq->dp.dpq.stats, 1, rte_pktmbuf_pkt_len(*pktp)); } else { added = pkt_start; } } if (likely(added != txq->added)) { sfc_ef100_tx_qpush(txq, added); txq->added = added; } #if SFC_TX_XMIT_PKTS_REAP_AT_LEAST_ONCE if (!reap_done) sfc_ef100_tx_reap(txq); #endif return pktp - &tx_pkts[0]; } static sfc_dp_tx_get_dev_info_t sfc_ef100_get_dev_info; static void sfc_ef100_get_dev_info(struct rte_eth_dev_info *dev_info) { /* * Number of descriptors just defines maximum number of pushed * descriptors (fill level). */ dev_info->tx_desc_lim.nb_min = 1; dev_info->tx_desc_lim.nb_align = 1; } static sfc_dp_tx_qsize_up_rings_t sfc_ef100_tx_qsize_up_rings; static int sfc_ef100_tx_qsize_up_rings(uint16_t nb_tx_desc, struct sfc_dp_tx_hw_limits *limits, unsigned int *txq_entries, unsigned int *evq_entries, unsigned int *txq_max_fill_level) { /* * rte_ethdev API guarantees that the number meets min, max and * alignment requirements. */ if (nb_tx_desc <= limits->txq_min_entries) *txq_entries = limits->txq_min_entries; else *txq_entries = rte_align32pow2(nb_tx_desc); *evq_entries = *txq_entries; *txq_max_fill_level = RTE_MIN(nb_tx_desc, SFC_EF100_TXQ_LIMIT(*evq_entries)); return 0; } static sfc_dp_tx_qcreate_t sfc_ef100_tx_qcreate; static int sfc_ef100_tx_qcreate(uint16_t port_id, uint16_t queue_id, const struct rte_pci_addr *pci_addr, int socket_id, const struct sfc_dp_tx_qcreate_info *info, struct sfc_dp_txq **dp_txqp) { struct sfc_ef100_txq *txq; int rc; rc = EINVAL; if (info->txq_entries != info->evq_entries) goto fail_bad_args; rc = ENOMEM; txq = rte_zmalloc_socket("sfc-ef100-txq", sizeof(*txq), RTE_CACHE_LINE_SIZE, socket_id); if (txq == NULL) goto fail_txq_alloc; sfc_dp_queue_init(&txq->dp.dpq, port_id, queue_id, pci_addr); rc = ENOMEM; txq->sw_ring = rte_calloc_socket("sfc-ef100-txq-sw_ring", info->txq_entries, sizeof(*txq->sw_ring), RTE_CACHE_LINE_SIZE, socket_id); if (txq->sw_ring == NULL) goto fail_sw_ring_alloc; txq->flags = SFC_EF100_TXQ_NOT_RUNNING; txq->ptr_mask = info->txq_entries - 1; txq->max_fill_level = info->max_fill_level; txq->free_thresh = info->free_thresh; txq->evq_phase_bit_shift = rte_bsf32(info->evq_entries); txq->txq_hw_ring = info->txq_hw_ring; txq->doorbell = (volatile uint8_t *)info->mem_bar + ER_GZ_TX_RING_DOORBELL_OFST + (info->hw_index << info->vi_window_shift); txq->evq_hw_ring = info->evq_hw_ring; txq->tso_tcp_header_offset_limit = info->tso_tcp_header_offset_limit; txq->tso_max_nb_header_descs = info->tso_max_nb_header_descs; txq->tso_max_header_len = info->tso_max_header_len; txq->tso_max_nb_payload_descs = info->tso_max_nb_payload_descs; txq->tso_max_payload_len = info->tso_max_payload_len; txq->tso_max_nb_outgoing_frames = info->tso_max_nb_outgoing_frames; txq->nic_dma_info = info->nic_dma_info; if (txq->nic_dma_info->nb_regions > 0) txq->flags |= SFC_EF100_TXQ_NIC_DMA_MAP; sfc_ef100_tx_debug(txq, "TxQ doorbell is %p", txq->doorbell); *dp_txqp = &txq->dp; return 0; fail_sw_ring_alloc: rte_free(txq); fail_txq_alloc: fail_bad_args: return rc; } static sfc_dp_tx_qdestroy_t sfc_ef100_tx_qdestroy; static void sfc_ef100_tx_qdestroy(struct sfc_dp_txq *dp_txq) { struct sfc_ef100_txq *txq = sfc_ef100_txq_by_dp_txq(dp_txq); rte_free(txq->sw_ring); rte_free(txq); } static sfc_dp_tx_qstart_t sfc_ef100_tx_qstart; static int sfc_ef100_tx_qstart(struct sfc_dp_txq *dp_txq, unsigned int evq_read_ptr, unsigned int txq_desc_index) { struct sfc_ef100_txq *txq = sfc_ef100_txq_by_dp_txq(dp_txq); txq->evq_read_ptr = evq_read_ptr; txq->added = txq->completed = txq_desc_index; txq->flags |= SFC_EF100_TXQ_STARTED; txq->flags &= ~(SFC_EF100_TXQ_NOT_RUNNING | SFC_EF100_TXQ_EXCEPTION); return 0; } static sfc_dp_tx_qstop_t sfc_ef100_tx_qstop; static void sfc_ef100_tx_qstop(struct sfc_dp_txq *dp_txq, unsigned int *evq_read_ptr) { struct sfc_ef100_txq *txq = sfc_ef100_txq_by_dp_txq(dp_txq); txq->flags |= SFC_EF100_TXQ_NOT_RUNNING; *evq_read_ptr = txq->evq_read_ptr; } static sfc_dp_tx_qtx_ev_t sfc_ef100_tx_qtx_ev; static bool sfc_ef100_tx_qtx_ev(struct sfc_dp_txq *dp_txq, unsigned int num_descs) { struct sfc_ef100_txq *txq = sfc_ef100_txq_by_dp_txq(dp_txq); SFC_ASSERT(txq->flags & SFC_EF100_TXQ_NOT_RUNNING); sfc_ef100_tx_reap_num_descs(txq, num_descs); return false; } static sfc_dp_tx_qreap_t sfc_ef100_tx_qreap; static void sfc_ef100_tx_qreap(struct sfc_dp_txq *dp_txq) { struct sfc_ef100_txq *txq = sfc_ef100_txq_by_dp_txq(dp_txq); unsigned int completed; for (completed = txq->completed; completed != txq->added; ++completed) { struct sfc_ef100_tx_sw_desc *txd; txd = &txq->sw_ring[completed & txq->ptr_mask]; if (txd->mbuf != NULL) { rte_pktmbuf_free_seg(txd->mbuf); txd->mbuf = NULL; } } txq->flags &= ~SFC_EF100_TXQ_STARTED; } static unsigned int sfc_ef100_tx_qdesc_npending(struct sfc_ef100_txq *txq) { const unsigned int evq_old_read_ptr = txq->evq_read_ptr; unsigned int npending = 0; efx_qword_t tx_ev; if (unlikely(txq->flags & (SFC_EF100_TXQ_NOT_RUNNING | SFC_EF100_TXQ_EXCEPTION))) return 0; while (sfc_ef100_tx_get_event(txq, &tx_ev)) npending += EFX_QWORD_FIELD(tx_ev, ESF_GZ_EV_TXCMPL_NUM_DESC); /* * The function does not process events, so return event queue read * pointer to the original position to allow the events that were * read to be processed later */ txq->evq_read_ptr = evq_old_read_ptr; return npending; } static sfc_dp_tx_qdesc_status_t sfc_ef100_tx_qdesc_status; static int sfc_ef100_tx_qdesc_status(struct sfc_dp_txq *dp_txq, uint16_t offset) { struct sfc_ef100_txq *txq = sfc_ef100_txq_by_dp_txq(dp_txq); unsigned int pushed = txq->added - txq->completed; if (unlikely(offset > txq->ptr_mask)) return -EINVAL; if (unlikely(offset >= txq->max_fill_level)) return RTE_ETH_TX_DESC_UNAVAIL; return (offset >= pushed || offset < sfc_ef100_tx_qdesc_npending(txq)) ? RTE_ETH_TX_DESC_DONE : RTE_ETH_TX_DESC_FULL; } struct sfc_dp_tx sfc_ef100_tx = { .dp = { .name = SFC_KVARG_DATAPATH_EF100, .type = SFC_DP_TX, .hw_fw_caps = SFC_DP_HW_FW_CAP_EF100, }, .features = SFC_DP_TX_FEAT_MULTI_PROCESS | SFC_DP_TX_FEAT_STATS, .dev_offload_capa = 0, .queue_offload_capa = RTE_ETH_TX_OFFLOAD_VLAN_INSERT | RTE_ETH_TX_OFFLOAD_IPV4_CKSUM | RTE_ETH_TX_OFFLOAD_OUTER_IPV4_CKSUM | RTE_ETH_TX_OFFLOAD_OUTER_UDP_CKSUM | RTE_ETH_TX_OFFLOAD_UDP_CKSUM | RTE_ETH_TX_OFFLOAD_TCP_CKSUM | RTE_ETH_TX_OFFLOAD_MULTI_SEGS | RTE_ETH_TX_OFFLOAD_TCP_TSO | RTE_ETH_TX_OFFLOAD_VXLAN_TNL_TSO | RTE_ETH_TX_OFFLOAD_GENEVE_TNL_TSO, .get_dev_info = sfc_ef100_get_dev_info, .qsize_up_rings = sfc_ef100_tx_qsize_up_rings, .qcreate = sfc_ef100_tx_qcreate, .qdestroy = sfc_ef100_tx_qdestroy, .qstart = sfc_ef100_tx_qstart, .qtx_ev = sfc_ef100_tx_qtx_ev, .qstop = sfc_ef100_tx_qstop, .qreap = sfc_ef100_tx_qreap, .qdesc_status = sfc_ef100_tx_qdesc_status, .pkt_prepare = sfc_ef100_tx_prepare_pkts, .pkt_burst = sfc_ef100_xmit_pkts, };