1 /* SPDX-License-Identifier: BSD-3-Clause
2 * Copyright(c) 2014-2018 Broadcom
9 #include <rte_bitmap.h>
10 #include <rte_byteorder.h>
11 #include <rte_malloc.h>
12 #include <rte_memory.h>
15 #include "bnxt_ring.h"
18 #include "hsi_struct_def_dpdk.h"
19 #ifdef RTE_LIBRTE_IEEE1588
20 #include "bnxt_hwrm.h"
23 #include <bnxt_tf_common.h>
24 #include <ulp_mark_mgr.h>
30 static inline struct rte_mbuf *__bnxt_alloc_rx_data(struct rte_mempool *mb)
32 struct rte_mbuf *data;
34 data = rte_mbuf_raw_alloc(mb);
39 static inline int bnxt_alloc_rx_data(struct bnxt_rx_queue *rxq,
40 struct bnxt_rx_ring_info *rxr,
43 struct rx_prod_pkt_bd *rxbd = &rxr->rx_desc_ring[prod];
44 struct bnxt_sw_rx_bd *rx_buf = &rxr->rx_buf_ring[prod];
45 struct rte_mbuf *mbuf;
47 mbuf = __bnxt_alloc_rx_data(rxq->mb_pool);
49 rte_atomic64_inc(&rxq->rx_mbuf_alloc_fail);
54 mbuf->data_off = RTE_PKTMBUF_HEADROOM;
56 rxbd->address = rte_cpu_to_le_64(rte_mbuf_data_iova_default(mbuf));
61 static inline int bnxt_alloc_ag_data(struct bnxt_rx_queue *rxq,
62 struct bnxt_rx_ring_info *rxr,
65 struct rx_prod_pkt_bd *rxbd = &rxr->ag_desc_ring[prod];
66 struct bnxt_sw_rx_bd *rx_buf = &rxr->ag_buf_ring[prod];
67 struct rte_mbuf *mbuf;
70 PMD_DRV_LOG(ERR, "Jumbo Frame. rxbd is NULL\n");
75 PMD_DRV_LOG(ERR, "Jumbo Frame. rx_buf is NULL\n");
79 mbuf = __bnxt_alloc_rx_data(rxq->mb_pool);
81 rte_atomic64_inc(&rxq->rx_mbuf_alloc_fail);
86 mbuf->data_off = RTE_PKTMBUF_HEADROOM;
88 rxbd->address = rte_cpu_to_le_64(rte_mbuf_data_iova_default(mbuf));
93 static inline void bnxt_reuse_rx_mbuf(struct bnxt_rx_ring_info *rxr,
94 struct rte_mbuf *mbuf)
96 uint16_t prod = RING_NEXT(rxr->rx_ring_struct, rxr->rx_prod);
97 struct bnxt_sw_rx_bd *prod_rx_buf;
98 struct rx_prod_pkt_bd *prod_bd;
100 prod_rx_buf = &rxr->rx_buf_ring[prod];
102 RTE_ASSERT(prod_rx_buf->mbuf == NULL);
103 RTE_ASSERT(mbuf != NULL);
105 prod_rx_buf->mbuf = mbuf;
107 prod_bd = &rxr->rx_desc_ring[prod];
109 prod_bd->address = rte_cpu_to_le_64(rte_mbuf_data_iova_default(mbuf));
115 struct rte_mbuf *bnxt_consume_rx_buf(struct bnxt_rx_ring_info *rxr,
118 struct bnxt_sw_rx_bd *cons_rx_buf;
119 struct rte_mbuf *mbuf;
121 cons_rx_buf = &rxr->rx_buf_ring[cons];
122 RTE_ASSERT(cons_rx_buf->mbuf != NULL);
123 mbuf = cons_rx_buf->mbuf;
124 cons_rx_buf->mbuf = NULL;
128 static void bnxt_tpa_start(struct bnxt_rx_queue *rxq,
129 struct rx_tpa_start_cmpl *tpa_start,
130 struct rx_tpa_start_cmpl_hi *tpa_start1)
132 struct bnxt_rx_ring_info *rxr = rxq->rx_ring;
135 struct bnxt_tpa_info *tpa_info;
136 struct rte_mbuf *mbuf;
138 agg_id = bnxt_tpa_start_agg_id(rxq->bp, tpa_start);
140 data_cons = tpa_start->opaque;
141 tpa_info = &rxr->tpa_info[agg_id];
143 mbuf = bnxt_consume_rx_buf(rxr, data_cons);
145 bnxt_reuse_rx_mbuf(rxr, tpa_info->mbuf);
147 tpa_info->agg_count = 0;
148 tpa_info->mbuf = mbuf;
149 tpa_info->len = rte_le_to_cpu_32(tpa_start->len);
153 mbuf->pkt_len = rte_le_to_cpu_32(tpa_start->len);
154 mbuf->data_len = mbuf->pkt_len;
155 mbuf->port = rxq->port_id;
156 mbuf->ol_flags = PKT_RX_LRO;
157 if (likely(tpa_start->flags_type &
158 rte_cpu_to_le_32(RX_TPA_START_CMPL_FLAGS_RSS_VALID))) {
159 mbuf->hash.rss = rte_le_to_cpu_32(tpa_start->rss_hash);
160 mbuf->ol_flags |= PKT_RX_RSS_HASH;
162 mbuf->hash.fdir.id = rte_le_to_cpu_16(tpa_start1->cfa_code);
163 mbuf->ol_flags |= PKT_RX_FDIR | PKT_RX_FDIR_ID;
165 if (tpa_start1->flags2 &
166 rte_cpu_to_le_32(RX_TPA_START_CMPL_FLAGS2_META_FORMAT_VLAN)) {
167 mbuf->vlan_tci = rte_le_to_cpu_32(tpa_start1->metadata);
168 mbuf->ol_flags |= PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED;
170 if (likely(tpa_start1->flags2 &
171 rte_cpu_to_le_32(RX_TPA_START_CMPL_FLAGS2_L4_CS_CALC)))
172 mbuf->ol_flags |= PKT_RX_L4_CKSUM_GOOD;
174 /* recycle next mbuf */
175 data_cons = RING_NEXT(rxr->rx_ring_struct, data_cons);
176 bnxt_reuse_rx_mbuf(rxr, bnxt_consume_rx_buf(rxr, data_cons));
179 static int bnxt_agg_bufs_valid(struct bnxt_cp_ring_info *cpr,
180 uint8_t agg_bufs, uint32_t raw_cp_cons)
182 uint16_t last_cp_cons;
183 struct rx_pkt_cmpl *agg_cmpl;
185 raw_cp_cons = ADV_RAW_CMP(raw_cp_cons, agg_bufs);
186 last_cp_cons = RING_CMP(cpr->cp_ring_struct, raw_cp_cons);
187 agg_cmpl = (struct rx_pkt_cmpl *)&cpr->cp_desc_ring[last_cp_cons];
188 cpr->valid = FLIP_VALID(raw_cp_cons,
189 cpr->cp_ring_struct->ring_mask,
191 return CMP_VALID(agg_cmpl, raw_cp_cons, cpr->cp_ring_struct);
194 /* TPA consume agg buffer out of order, allocate connected data only */
195 static int bnxt_prod_ag_mbuf(struct bnxt_rx_queue *rxq)
197 struct bnxt_rx_ring_info *rxr = rxq->rx_ring;
198 uint16_t next = RING_NEXT(rxr->ag_ring_struct, rxr->ag_prod);
200 /* TODO batch allocation for better performance */
201 while (rte_bitmap_get(rxr->ag_bitmap, next)) {
202 if (unlikely(bnxt_alloc_ag_data(rxq, rxr, next))) {
204 "agg mbuf alloc failed: prod=0x%x\n", next);
207 rte_bitmap_clear(rxr->ag_bitmap, next);
209 next = RING_NEXT(rxr->ag_ring_struct, next);
215 static int bnxt_rx_pages(struct bnxt_rx_queue *rxq,
216 struct rte_mbuf *mbuf, uint32_t *tmp_raw_cons,
217 uint8_t agg_buf, struct bnxt_tpa_info *tpa_info)
219 struct bnxt_cp_ring_info *cpr = rxq->cp_ring;
220 struct bnxt_rx_ring_info *rxr = rxq->rx_ring;
222 uint16_t cp_cons, ag_cons;
223 struct rx_pkt_cmpl *rxcmp;
224 struct rte_mbuf *last = mbuf;
225 bool is_thor_tpa = tpa_info && BNXT_CHIP_THOR(rxq->bp);
227 for (i = 0; i < agg_buf; i++) {
228 struct bnxt_sw_rx_bd *ag_buf;
229 struct rte_mbuf *ag_mbuf;
232 rxcmp = (void *)&tpa_info->agg_arr[i];
234 *tmp_raw_cons = NEXT_RAW_CMP(*tmp_raw_cons);
235 cp_cons = RING_CMP(cpr->cp_ring_struct, *tmp_raw_cons);
236 rxcmp = (struct rx_pkt_cmpl *)
237 &cpr->cp_desc_ring[cp_cons];
241 bnxt_dump_cmpl(cp_cons, rxcmp);
244 ag_cons = rxcmp->opaque;
245 RTE_ASSERT(ag_cons <= rxr->ag_ring_struct->ring_mask);
246 ag_buf = &rxr->ag_buf_ring[ag_cons];
247 ag_mbuf = ag_buf->mbuf;
248 RTE_ASSERT(ag_mbuf != NULL);
250 ag_mbuf->data_len = rte_le_to_cpu_16(rxcmp->len);
253 mbuf->pkt_len += ag_mbuf->data_len;
255 last->next = ag_mbuf;
261 * As aggregation buffer consumed out of order in TPA module,
262 * use bitmap to track freed slots to be allocated and notified
265 rte_bitmap_set(rxr->ag_bitmap, ag_cons);
267 bnxt_prod_ag_mbuf(rxq);
271 static inline struct rte_mbuf *bnxt_tpa_end(
272 struct bnxt_rx_queue *rxq,
273 uint32_t *raw_cp_cons,
274 struct rx_tpa_end_cmpl *tpa_end,
275 struct rx_tpa_end_cmpl_hi *tpa_end1)
277 struct bnxt_cp_ring_info *cpr = rxq->cp_ring;
278 struct bnxt_rx_ring_info *rxr = rxq->rx_ring;
280 struct rte_mbuf *mbuf;
282 uint8_t payload_offset;
283 struct bnxt_tpa_info *tpa_info;
285 if (BNXT_CHIP_THOR(rxq->bp)) {
286 struct rx_tpa_v2_end_cmpl *th_tpa_end;
287 struct rx_tpa_v2_end_cmpl_hi *th_tpa_end1;
289 th_tpa_end = (void *)tpa_end;
290 th_tpa_end1 = (void *)tpa_end1;
291 agg_id = BNXT_TPA_END_AGG_ID_TH(th_tpa_end);
292 agg_bufs = BNXT_TPA_END_AGG_BUFS_TH(th_tpa_end1);
293 payload_offset = th_tpa_end1->payload_offset;
295 agg_id = BNXT_TPA_END_AGG_ID(tpa_end);
296 agg_bufs = BNXT_TPA_END_AGG_BUFS(tpa_end);
297 if (!bnxt_agg_bufs_valid(cpr, agg_bufs, *raw_cp_cons))
299 payload_offset = tpa_end->payload_offset;
302 tpa_info = &rxr->tpa_info[agg_id];
303 mbuf = tpa_info->mbuf;
304 RTE_ASSERT(mbuf != NULL);
308 bnxt_rx_pages(rxq, mbuf, raw_cp_cons, agg_bufs, tpa_info);
310 mbuf->l4_len = payload_offset;
312 struct rte_mbuf *new_data = __bnxt_alloc_rx_data(rxq->mb_pool);
313 RTE_ASSERT(new_data != NULL);
315 rte_atomic64_inc(&rxq->rx_mbuf_alloc_fail);
318 tpa_info->mbuf = new_data;
324 bnxt_parse_pkt_type(struct rx_pkt_cmpl *rxcmp, struct rx_pkt_cmpl_hi *rxcmp1)
326 uint32_t l3, pkt_type = 0;
327 uint32_t t_ipcs = 0, ip6 = 0, vlan = 0;
330 vlan = !!(rxcmp1->flags2 &
331 rte_cpu_to_le_32(RX_PKT_CMPL_FLAGS2_META_FORMAT_VLAN));
332 pkt_type |= vlan ? RTE_PTYPE_L2_ETHER_VLAN : RTE_PTYPE_L2_ETHER;
334 t_ipcs = !!(rxcmp1->flags2 &
335 rte_cpu_to_le_32(RX_PKT_CMPL_FLAGS2_T_IP_CS_CALC));
336 ip6 = !!(rxcmp1->flags2 &
337 rte_cpu_to_le_32(RX_PKT_CMPL_FLAGS2_IP_TYPE));
339 flags_type = rxcmp->flags_type &
340 rte_cpu_to_le_32(RX_PKT_CMPL_FLAGS_ITYPE_MASK);
343 l3 = RTE_PTYPE_L3_IPV4_EXT_UNKNOWN;
344 else if (!t_ipcs && ip6)
345 l3 = RTE_PTYPE_L3_IPV6_EXT_UNKNOWN;
346 else if (t_ipcs && !ip6)
347 l3 = RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN;
349 l3 = RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN;
351 switch (flags_type) {
352 case RTE_LE32(RX_PKT_CMPL_FLAGS_ITYPE_ICMP):
354 pkt_type |= l3 | RTE_PTYPE_L4_ICMP;
356 pkt_type |= l3 | RTE_PTYPE_INNER_L4_ICMP;
359 case RTE_LE32(RX_PKT_CMPL_FLAGS_ITYPE_TCP):
361 pkt_type |= l3 | RTE_PTYPE_L4_TCP;
363 pkt_type |= l3 | RTE_PTYPE_INNER_L4_TCP;
366 case RTE_LE32(RX_PKT_CMPL_FLAGS_ITYPE_UDP):
368 pkt_type |= l3 | RTE_PTYPE_L4_UDP;
370 pkt_type |= l3 | RTE_PTYPE_INNER_L4_UDP;
373 case RTE_LE32(RX_PKT_CMPL_FLAGS_ITYPE_IP):
381 #ifdef RTE_LIBRTE_IEEE1588
383 bnxt_get_rx_ts_thor(struct bnxt *bp, uint32_t rx_ts_cmpl)
385 uint64_t systime_cycles = 0;
387 if (!BNXT_CHIP_THOR(bp))
390 /* On Thor, Rx timestamps are provided directly in the
391 * Rx completion records to the driver. Only 32 bits of
392 * the timestamp is present in the completion. Driver needs
393 * to read the current 48 bit free running timer using the
394 * HWRM_PORT_TS_QUERY command and combine the upper 16 bits
395 * from the HWRM response with the lower 32 bits in the
396 * Rx completion to produce the 48 bit timestamp for the Rx packet
398 bnxt_hwrm_port_ts_query(bp, BNXT_PTP_FLAGS_CURRENT_TIME,
400 bp->ptp_cfg->rx_timestamp = (systime_cycles & 0xFFFF00000000);
401 bp->ptp_cfg->rx_timestamp |= rx_ts_cmpl;
406 bnxt_ulp_set_mark_in_mbuf(struct bnxt *bp, struct rx_pkt_cmpl_hi *rxcmp1,
407 struct rte_mbuf *mbuf)
417 cfa_code = rte_le_to_cpu_16(rxcmp1->cfa_code);
418 flags2 = rte_le_to_cpu_32(rxcmp1->flags2);
419 meta = rte_le_to_cpu_32(rxcmp1->metadata);
421 meta >>= BNXT_RX_META_CFA_CODE_SHIFT;
423 /* The flags field holds extra bits of info from [6:4]
424 * which indicate if the flow is in TCAM or EM or EEM
426 meta_fmt = (flags2 & BNXT_CFA_META_FMT_MASK) >>
427 BNXT_CFA_META_FMT_SHFT;
428 /* meta_fmt == 4 => 'b100 => 'b10x => EM.
429 * meta_fmt == 5 => 'b101 => 'b10x => EM + VLAN
430 * meta_fmt == 6 => 'b110 => 'b11x => EEM
431 * meta_fmt == 7 => 'b111 => 'b11x => EEM + VLAN.
433 meta_fmt >>= BNXT_CFA_META_FMT_EM_EEM_SHFT;
435 eem = meta_fmt == BNXT_CFA_META_FMT_EEM;
437 /* For EEM flows, The first part of cfa_code is 16 bits.
438 * The second part is embedded in the
439 * metadata field from bit 19 onwards. The driver needs to
440 * ignore the first 19 bits of metadata and use the next 12
441 * bits as higher 12 bits of cfa_code.
444 cfa_code |= meta << BNXT_CFA_CODE_META_SHIFT;
448 mbuf->hash.fdir.hi = 0;
449 mbuf->hash.fdir.id = 0;
451 rc = ulp_mark_db_mark_get(&bp->ulp_ctx, true,
454 rc = ulp_mark_db_mark_get(&bp->ulp_ctx, false,
456 /* If the above fails, simply return and don't add the mark to
462 mbuf->hash.fdir.hi = mark_id;
463 mbuf->udata64 = (cfa_code & 0xffffffffull) << 32;
464 mbuf->hash.fdir.id = rxcmp1->cfa_code;
465 mbuf->ol_flags |= PKT_RX_FDIR | PKT_RX_FDIR_ID;
469 void bnxt_set_mark_in_mbuf(struct bnxt *bp,
470 struct rx_pkt_cmpl_hi *rxcmp1,
471 struct rte_mbuf *mbuf)
473 uint32_t cfa_code = 0;
474 uint8_t meta_fmt = 0;
478 cfa_code = rte_le_to_cpu_16(rxcmp1->cfa_code);
482 if (cfa_code && !bp->mark_table[cfa_code].valid)
485 flags2 = rte_le_to_cpu_16(rxcmp1->flags2);
486 meta = rte_le_to_cpu_32(rxcmp1->metadata);
488 meta >>= BNXT_RX_META_CFA_CODE_SHIFT;
490 /* The flags field holds extra bits of info from [6:4]
491 * which indicate if the flow is in TCAM or EM or EEM
493 meta_fmt = (flags2 & BNXT_CFA_META_FMT_MASK) >>
494 BNXT_CFA_META_FMT_SHFT;
496 /* meta_fmt == 4 => 'b100 => 'b10x => EM.
497 * meta_fmt == 5 => 'b101 => 'b10x => EM + VLAN
498 * meta_fmt == 6 => 'b110 => 'b11x => EEM
499 * meta_fmt == 7 => 'b111 => 'b11x => EEM + VLAN.
501 meta_fmt >>= BNXT_CFA_META_FMT_EM_EEM_SHFT;
504 mbuf->hash.fdir.hi = bp->mark_table[cfa_code].mark_id;
505 mbuf->ol_flags |= PKT_RX_FDIR | PKT_RX_FDIR_ID;
508 static int bnxt_rx_pkt(struct rte_mbuf **rx_pkt,
509 struct bnxt_rx_queue *rxq, uint32_t *raw_cons)
511 struct bnxt_cp_ring_info *cpr = rxq->cp_ring;
512 struct bnxt_rx_ring_info *rxr = rxq->rx_ring;
513 struct rx_pkt_cmpl *rxcmp;
514 struct rx_pkt_cmpl_hi *rxcmp1;
515 uint32_t tmp_raw_cons = *raw_cons;
516 uint16_t cons, prod, cp_cons =
517 RING_CMP(cpr->cp_ring_struct, tmp_raw_cons);
518 struct rte_mbuf *mbuf;
522 uint32_t flags2_f = 0;
524 struct bnxt *bp = rxq->bp;
526 rxcmp = (struct rx_pkt_cmpl *)
527 &cpr->cp_desc_ring[cp_cons];
529 cmp_type = CMP_TYPE(rxcmp);
531 if (cmp_type == RX_TPA_V2_ABUF_CMPL_TYPE_RX_TPA_AGG) {
532 struct rx_tpa_v2_abuf_cmpl *rx_agg = (void *)rxcmp;
533 uint16_t agg_id = rte_cpu_to_le_16(rx_agg->agg_id);
534 struct bnxt_tpa_info *tpa_info;
536 tpa_info = &rxr->tpa_info[agg_id];
537 RTE_ASSERT(tpa_info->agg_count < 16);
538 tpa_info->agg_arr[tpa_info->agg_count++] = *rx_agg;
539 rc = -EINVAL; /* Continue w/o new mbuf */
543 tmp_raw_cons = NEXT_RAW_CMP(tmp_raw_cons);
544 cp_cons = RING_CMP(cpr->cp_ring_struct, tmp_raw_cons);
545 rxcmp1 = (struct rx_pkt_cmpl_hi *)&cpr->cp_desc_ring[cp_cons];
547 if (!CMP_VALID(rxcmp1, tmp_raw_cons, cpr->cp_ring_struct))
550 cpr->valid = FLIP_VALID(cp_cons,
551 cpr->cp_ring_struct->ring_mask,
554 if (cmp_type == RX_TPA_START_CMPL_TYPE_RX_TPA_START) {
555 bnxt_tpa_start(rxq, (struct rx_tpa_start_cmpl *)rxcmp,
556 (struct rx_tpa_start_cmpl_hi *)rxcmp1);
557 rc = -EINVAL; /* Continue w/o new mbuf */
559 } else if (cmp_type == RX_TPA_END_CMPL_TYPE_RX_TPA_END) {
560 mbuf = bnxt_tpa_end(rxq, &tmp_raw_cons,
561 (struct rx_tpa_end_cmpl *)rxcmp,
562 (struct rx_tpa_end_cmpl_hi *)rxcmp1);
567 } else if (cmp_type != 0x11) {
572 agg_buf = (rxcmp->agg_bufs_v1 & RX_PKT_CMPL_AGG_BUFS_MASK)
573 >> RX_PKT_CMPL_AGG_BUFS_SFT;
574 if (agg_buf && !bnxt_agg_bufs_valid(cpr, agg_buf, tmp_raw_cons))
579 cons = rxcmp->opaque;
580 mbuf = bnxt_consume_rx_buf(rxr, cons);
586 mbuf->data_off = RTE_PKTMBUF_HEADROOM;
589 mbuf->pkt_len = rxcmp->len;
590 mbuf->data_len = mbuf->pkt_len;
591 mbuf->port = rxq->port_id;
594 flags_type = rte_le_to_cpu_16(rxcmp->flags_type);
595 if (flags_type & RX_PKT_CMPL_FLAGS_RSS_VALID) {
596 mbuf->hash.rss = rxcmp->rss_hash;
597 mbuf->ol_flags |= PKT_RX_RSS_HASH;
601 bnxt_ulp_set_mark_in_mbuf(rxq->bp, rxcmp1, mbuf);
603 bnxt_set_mark_in_mbuf(rxq->bp, rxcmp1, mbuf);
605 #ifdef RTE_LIBRTE_IEEE1588
606 if (unlikely((flags_type & RX_PKT_CMPL_FLAGS_MASK) ==
607 RX_PKT_CMPL_FLAGS_ITYPE_PTP_W_TIMESTAMP)) {
608 mbuf->ol_flags |= PKT_RX_IEEE1588_PTP | PKT_RX_IEEE1588_TMST;
609 bnxt_get_rx_ts_thor(rxq->bp, rxcmp1->reorder);
613 bnxt_rx_pages(rxq, mbuf, &tmp_raw_cons, agg_buf, NULL);
615 if (rxcmp1->flags2 & RX_PKT_CMPL_FLAGS2_META_FORMAT_VLAN) {
616 mbuf->vlan_tci = rxcmp1->metadata &
617 (RX_PKT_CMPL_METADATA_VID_MASK |
618 RX_PKT_CMPL_METADATA_DE |
619 RX_PKT_CMPL_METADATA_PRI_MASK);
620 mbuf->ol_flags |= PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED;
623 flags2_f = flags2_0xf(rxcmp1);
625 if (likely(IS_IP_NONTUNNEL_PKT(flags2_f))) {
626 if (unlikely(RX_CMP_IP_CS_ERROR(rxcmp1)))
627 mbuf->ol_flags |= PKT_RX_IP_CKSUM_BAD;
628 else if (unlikely(RX_CMP_IP_CS_UNKNOWN(rxcmp1)))
629 mbuf->ol_flags |= PKT_RX_IP_CKSUM_UNKNOWN;
631 mbuf->ol_flags |= PKT_RX_IP_CKSUM_GOOD;
632 } else if (IS_IP_TUNNEL_PKT(flags2_f)) {
633 if (unlikely(RX_CMP_IP_OUTER_CS_ERROR(rxcmp1) ||
634 RX_CMP_IP_CS_ERROR(rxcmp1)))
635 mbuf->ol_flags |= PKT_RX_IP_CKSUM_BAD;
636 else if (unlikely(RX_CMP_IP_CS_UNKNOWN(rxcmp1)))
637 mbuf->ol_flags |= PKT_RX_IP_CKSUM_UNKNOWN;
639 mbuf->ol_flags |= PKT_RX_IP_CKSUM_GOOD;
643 if (likely(IS_L4_NONTUNNEL_PKT(flags2_f))) {
644 if (unlikely(RX_CMP_L4_INNER_CS_ERR2(rxcmp1)))
645 mbuf->ol_flags |= PKT_RX_L4_CKSUM_BAD;
647 mbuf->ol_flags |= PKT_RX_L4_CKSUM_GOOD;
648 } else if (IS_L4_TUNNEL_PKT(flags2_f)) {
649 if (unlikely(RX_CMP_L4_INNER_CS_ERR2(rxcmp1)))
650 mbuf->ol_flags |= PKT_RX_L4_CKSUM_BAD;
652 mbuf->ol_flags |= PKT_RX_L4_CKSUM_GOOD;
653 if (unlikely(RX_CMP_L4_OUTER_CS_ERR2(rxcmp1))) {
654 mbuf->ol_flags |= PKT_RX_OUTER_L4_CKSUM_BAD;
655 } else if (unlikely(IS_L4_TUNNEL_PKT_ONLY_INNER_L4_CS
657 mbuf->ol_flags |= PKT_RX_OUTER_L4_CKSUM_UNKNOWN;
659 mbuf->ol_flags |= PKT_RX_OUTER_L4_CKSUM_GOOD;
661 } else if (unlikely(RX_CMP_L4_CS_UNKNOWN(rxcmp1))) {
662 mbuf->ol_flags |= PKT_RX_L4_CKSUM_UNKNOWN;
665 mbuf->packet_type = bnxt_parse_pkt_type(rxcmp, rxcmp1);
668 if (rxcmp1->errors_v2 & RX_CMP_L2_ERRORS) {
669 /* Re-install the mbuf back to the rx ring */
670 bnxt_reuse_rx_mbuf(rxr, cons, mbuf);
677 * TODO: Redesign this....
678 * If the allocation fails, the packet does not get received.
679 * Simply returning this will result in slowly falling behind
680 * on the producer ring buffers.
681 * Instead, "filling up" the producer just before ringing the
682 * doorbell could be a better solution since it will let the
683 * producer ring starve until memory is available again pushing
684 * the drops into hardware and getting them out of the driver
685 * allowing recovery to a full producer ring.
687 * This could also help with cache usage by preventing per-packet
688 * calls in favour of a tight loop with the same function being called
691 prod = RING_NEXT(rxr->rx_ring_struct, prod);
692 if (bnxt_alloc_rx_data(rxq, rxr, prod)) {
693 PMD_DRV_LOG(ERR, "mbuf alloc failed with prod=0x%x\n", prod);
699 * All MBUFs are allocated with the same size under DPDK,
700 * no optimization for rx_copy_thresh
707 *raw_cons = tmp_raw_cons;
712 uint16_t bnxt_recv_pkts(void *rx_queue, struct rte_mbuf **rx_pkts,
715 struct bnxt_rx_queue *rxq = rx_queue;
716 struct bnxt_cp_ring_info *cpr = rxq->cp_ring;
717 struct bnxt_rx_ring_info *rxr = rxq->rx_ring;
718 uint32_t raw_cons = cpr->cp_raw_cons;
721 struct rx_pkt_cmpl *rxcmp;
722 uint16_t prod = rxr->rx_prod;
723 uint16_t ag_prod = rxr->ag_prod;
727 if (unlikely(is_bnxt_in_error(rxq->bp)))
730 /* If Rx Q was stopped return */
731 if (unlikely(!rxq->rx_started ||
732 !rte_spinlock_trylock(&rxq->lock)))
735 /* Handle RX burst request */
737 cons = RING_CMP(cpr->cp_ring_struct, raw_cons);
738 rte_prefetch0(&cpr->cp_desc_ring[cons]);
739 rxcmp = (struct rx_pkt_cmpl *)&cpr->cp_desc_ring[cons];
741 if (!CMP_VALID(rxcmp, raw_cons, cpr->cp_ring_struct))
743 cpr->valid = FLIP_VALID(cons,
744 cpr->cp_ring_struct->ring_mask,
747 /* TODO: Avoid magic numbers... */
748 if ((CMP_TYPE(rxcmp) & 0x30) == 0x10) {
749 rc = bnxt_rx_pkt(&rx_pkts[nb_rx_pkts], rxq, &raw_cons);
750 if (likely(!rc) || rc == -ENOMEM)
752 if (rc == -EBUSY) /* partial completion */
754 } else if (!BNXT_NUM_ASYNC_CPR(rxq->bp)) {
756 bnxt_event_hwrm_resp_handler(rxq->bp,
757 (struct cmpl_base *)rxcmp);
758 /* If the async event is Fatal error, return */
759 if (unlikely(is_bnxt_in_error(rxq->bp)))
763 raw_cons = NEXT_RAW_CMP(raw_cons);
764 if (nb_rx_pkts == nb_pkts || evt)
766 /* Post some Rx buf early in case of larger burst processing */
767 if (nb_rx_pkts == BNXT_RX_POST_THRESH)
768 bnxt_db_write(&rxr->rx_db, rxr->rx_prod);
771 cpr->cp_raw_cons = raw_cons;
772 if (!nb_rx_pkts && !evt) {
774 * For PMD, there is no need to keep on pushing to REARM
775 * the doorbell if there are no new completions
780 if (prod != rxr->rx_prod)
781 bnxt_db_write(&rxr->rx_db, rxr->rx_prod);
783 /* Ring the AGG ring DB */
784 if (ag_prod != rxr->ag_prod)
785 bnxt_db_write(&rxr->ag_db, rxr->ag_prod);
789 /* Attempt to alloc Rx buf in case of a previous allocation failure. */
791 int i = RING_NEXT(rxr->rx_ring_struct, prod);
792 int cnt = nb_rx_pkts;
795 i = RING_NEXT(rxr->rx_ring_struct, i), cnt--) {
796 struct bnxt_sw_rx_bd *rx_buf = &rxr->rx_buf_ring[i];
798 /* Buffer already allocated for this index. */
799 if (rx_buf->mbuf != NULL)
802 /* This slot is empty. Alloc buffer for Rx */
803 if (!bnxt_alloc_rx_data(rxq, rxr, i)) {
805 bnxt_db_write(&rxr->rx_db, rxr->rx_prod);
807 PMD_DRV_LOG(ERR, "Alloc mbuf failed\n");
814 rte_spinlock_unlock(&rxq->lock);
820 * Dummy DPDK callback for RX.
822 * This function is used to temporarily replace the real callback during
823 * unsafe control operations on the queue, or in case of error.
826 bnxt_dummy_recv_pkts(void *rx_queue __rte_unused,
827 struct rte_mbuf **rx_pkts __rte_unused,
828 uint16_t nb_pkts __rte_unused)
833 void bnxt_free_rx_rings(struct bnxt *bp)
836 struct bnxt_rx_queue *rxq;
841 for (i = 0; i < (int)bp->rx_nr_rings; i++) {
842 rxq = bp->rx_queues[i];
846 bnxt_free_ring(rxq->rx_ring->rx_ring_struct);
847 rte_free(rxq->rx_ring->rx_ring_struct);
849 /* Free the Aggregator ring */
850 bnxt_free_ring(rxq->rx_ring->ag_ring_struct);
851 rte_free(rxq->rx_ring->ag_ring_struct);
852 rxq->rx_ring->ag_ring_struct = NULL;
854 rte_free(rxq->rx_ring);
856 bnxt_free_ring(rxq->cp_ring->cp_ring_struct);
857 rte_free(rxq->cp_ring->cp_ring_struct);
858 rte_free(rxq->cp_ring);
861 bp->rx_queues[i] = NULL;
865 int bnxt_init_rx_ring_struct(struct bnxt_rx_queue *rxq, unsigned int socket_id)
867 struct bnxt_cp_ring_info *cpr;
868 struct bnxt_rx_ring_info *rxr;
869 struct bnxt_ring *ring;
871 rxq->rx_buf_size = BNXT_MAX_PKT_LEN + sizeof(struct rte_mbuf);
873 rxr = rte_zmalloc_socket("bnxt_rx_ring",
874 sizeof(struct bnxt_rx_ring_info),
875 RTE_CACHE_LINE_SIZE, socket_id);
880 ring = rte_zmalloc_socket("bnxt_rx_ring_struct",
881 sizeof(struct bnxt_ring),
882 RTE_CACHE_LINE_SIZE, socket_id);
885 rxr->rx_ring_struct = ring;
886 ring->ring_size = rte_align32pow2(rxq->nb_rx_desc);
887 ring->ring_mask = ring->ring_size - 1;
888 ring->bd = (void *)rxr->rx_desc_ring;
889 ring->bd_dma = rxr->rx_desc_mapping;
890 ring->vmem_size = ring->ring_size * sizeof(struct bnxt_sw_rx_bd);
891 ring->vmem = (void **)&rxr->rx_buf_ring;
893 cpr = rte_zmalloc_socket("bnxt_rx_ring",
894 sizeof(struct bnxt_cp_ring_info),
895 RTE_CACHE_LINE_SIZE, socket_id);
900 ring = rte_zmalloc_socket("bnxt_rx_ring_struct",
901 sizeof(struct bnxt_ring),
902 RTE_CACHE_LINE_SIZE, socket_id);
905 cpr->cp_ring_struct = ring;
906 ring->ring_size = rte_align32pow2(rxr->rx_ring_struct->ring_size *
907 (2 + AGG_RING_SIZE_FACTOR));
908 ring->ring_mask = ring->ring_size - 1;
909 ring->bd = (void *)cpr->cp_desc_ring;
910 ring->bd_dma = cpr->cp_desc_mapping;
914 /* Allocate Aggregator rings */
915 ring = rte_zmalloc_socket("bnxt_rx_ring_struct",
916 sizeof(struct bnxt_ring),
917 RTE_CACHE_LINE_SIZE, socket_id);
920 rxr->ag_ring_struct = ring;
921 ring->ring_size = rte_align32pow2(rxq->nb_rx_desc *
922 AGG_RING_SIZE_FACTOR);
923 ring->ring_mask = ring->ring_size - 1;
924 ring->bd = (void *)rxr->ag_desc_ring;
925 ring->bd_dma = rxr->ag_desc_mapping;
926 ring->vmem_size = ring->ring_size * sizeof(struct bnxt_sw_rx_bd);
927 ring->vmem = (void **)&rxr->ag_buf_ring;
932 static void bnxt_init_rxbds(struct bnxt_ring *ring, uint32_t type,
936 struct rx_prod_pkt_bd *rx_bd_ring = (struct rx_prod_pkt_bd *)ring->bd;
940 for (j = 0; j < ring->ring_size; j++) {
941 rx_bd_ring[j].flags_type = rte_cpu_to_le_16(type);
942 rx_bd_ring[j].len = rte_cpu_to_le_16(len);
943 rx_bd_ring[j].opaque = j;
947 int bnxt_init_one_rx_ring(struct bnxt_rx_queue *rxq)
949 struct bnxt_rx_ring_info *rxr;
950 struct bnxt_ring *ring;
955 size = rte_pktmbuf_data_room_size(rxq->mb_pool) - RTE_PKTMBUF_HEADROOM;
956 size = RTE_MIN(BNXT_MAX_PKT_LEN, size);
958 type = RX_PROD_PKT_BD_TYPE_RX_PROD_PKT | RX_PROD_PKT_BD_FLAGS_EOP_PAD;
961 ring = rxr->rx_ring_struct;
962 bnxt_init_rxbds(ring, type, size);
965 for (i = 0; i < ring->ring_size; i++) {
966 if (bnxt_alloc_rx_data(rxq, rxr, prod) != 0) {
968 "init'ed rx ring %d with %d/%d mbufs only\n",
969 rxq->queue_id, i, ring->ring_size);
973 prod = RING_NEXT(rxr->rx_ring_struct, prod);
976 ring = rxr->ag_ring_struct;
977 type = RX_PROD_AGG_BD_TYPE_RX_PROD_AGG;
978 bnxt_init_rxbds(ring, type, size);
981 for (i = 0; i < ring->ring_size; i++) {
982 if (bnxt_alloc_ag_data(rxq, rxr, prod) != 0) {
984 "init'ed AG ring %d with %d/%d mbufs only\n",
985 rxq->queue_id, i, ring->ring_size);
989 prod = RING_NEXT(rxr->ag_ring_struct, prod);
991 PMD_DRV_LOG(DEBUG, "AGG Done!\n");
994 unsigned int max_aggs = BNXT_TPA_MAX_AGGS(rxq->bp);
996 for (i = 0; i < max_aggs; i++) {
997 rxr->tpa_info[i].mbuf =
998 __bnxt_alloc_rx_data(rxq->mb_pool);
999 if (!rxr->tpa_info[i].mbuf) {
1000 rte_atomic64_inc(&rxq->rx_mbuf_alloc_fail);
1005 PMD_DRV_LOG(DEBUG, "TPA alloc Done!\n");