1 /* SPDX-License-Identifier: BSD-3-Clause
2 * Copyright 2015 6WIND S.A.
3 * Copyright 2015-2019 Mellanox Technologies, Ltd
12 /* ISO C doesn't support unnamed structs/unions, disabling -pedantic. */
14 #pragma GCC diagnostic ignored "-Wpedantic"
16 #include <infiniband/verbs.h>
17 #include <infiniband/mlx5dv.h>
19 #pragma GCC diagnostic error "-Wpedantic"
23 #include <rte_mempool.h>
24 #include <rte_prefetch.h>
25 #include <rte_common.h>
26 #include <rte_branch_prediction.h>
27 #include <rte_ether.h>
28 #include <rte_cycles.h>
31 #include "mlx5_utils.h"
32 #include "mlx5_rxtx.h"
33 #include "mlx5_autoconf.h"
34 #include "mlx5_defs.h"
37 /* TX burst subroutines return codes. */
38 enum mlx5_txcmp_code {
39 MLX5_TXCMP_CODE_EXIT = 0,
40 MLX5_TXCMP_CODE_ERROR,
41 MLX5_TXCMP_CODE_SINGLE,
42 MLX5_TXCMP_CODE_MULTI,
48 * These defines are used to configure Tx burst routine option set
49 * supported at compile time. The not specified options are optimized out
50 * out due to if conditions can be explicitly calculated at compile time.
51 * The offloads with bigger runtime check (require more CPU cycles to
52 * skip) overhead should have the bigger index - this is needed to
53 * select the better matching routine function if no exact match and
54 * some offloads are not actually requested.
56 #define MLX5_TXOFF_CONFIG_MULTI (1u << 0) /* Multi-segment packets.*/
57 #define MLX5_TXOFF_CONFIG_TSO (1u << 1) /* TCP send offload supported.*/
58 #define MLX5_TXOFF_CONFIG_SWP (1u << 2) /* Tunnels/SW Parser offloads.*/
59 #define MLX5_TXOFF_CONFIG_CSUM (1u << 3) /* Check Sums offloaded. */
60 #define MLX5_TXOFF_CONFIG_INLINE (1u << 4) /* Data inlining supported. */
61 #define MLX5_TXOFF_CONFIG_VLAN (1u << 5) /* VLAN insertion supported.*/
62 #define MLX5_TXOFF_CONFIG_METADATA (1u << 6) /* Flow metadata. */
63 #define MLX5_TXOFF_CONFIG_EMPW (1u << 8) /* Enhanced MPW supported.*/
65 /* The most common offloads groups. */
66 #define MLX5_TXOFF_CONFIG_NONE 0
67 #define MLX5_TXOFF_CONFIG_FULL (MLX5_TXOFF_CONFIG_MULTI | \
68 MLX5_TXOFF_CONFIG_TSO | \
69 MLX5_TXOFF_CONFIG_SWP | \
70 MLX5_TXOFF_CONFIG_CSUM | \
71 MLX5_TXOFF_CONFIG_INLINE | \
72 MLX5_TXOFF_CONFIG_VLAN | \
73 MLX5_TXOFF_CONFIG_METADATA)
75 #define MLX5_TXOFF_CONFIG(mask) (olx & MLX5_TXOFF_CONFIG_##mask)
77 #define MLX5_TXOFF_DECL(func, olx) \
78 static uint16_t mlx5_tx_burst_##func(void *txq, \
79 struct rte_mbuf **pkts, \
82 return mlx5_tx_burst_tmpl((struct mlx5_txq_data *)txq, \
83 pkts, pkts_n, (olx)); \
86 #define MLX5_TXOFF_INFO(func, olx) {mlx5_tx_burst_##func, olx},
88 static __rte_always_inline uint32_t
89 rxq_cq_to_pkt_type(struct mlx5_rxq_data *rxq, volatile struct mlx5_cqe *cqe);
91 static __rte_always_inline int
92 mlx5_rx_poll_len(struct mlx5_rxq_data *rxq, volatile struct mlx5_cqe *cqe,
93 uint16_t cqe_cnt, volatile struct mlx5_mini_cqe8 **mcqe);
95 static __rte_always_inline uint32_t
96 rxq_cq_to_ol_flags(volatile struct mlx5_cqe *cqe);
98 static __rte_always_inline void
99 rxq_cq_to_mbuf(struct mlx5_rxq_data *rxq, struct rte_mbuf *pkt,
100 volatile struct mlx5_cqe *cqe, uint32_t rss_hash_res);
102 static __rte_always_inline void
103 mprq_buf_replace(struct mlx5_rxq_data *rxq, uint16_t rq_idx,
104 const unsigned int strd_n);
107 mlx5_queue_state_modify(struct rte_eth_dev *dev,
108 struct mlx5_mp_arg_queue_state_modify *sm);
111 mlx5_lro_update_tcp_hdr(struct rte_tcp_hdr *restrict tcp,
112 volatile struct mlx5_cqe *restrict cqe,
116 mlx5_lro_update_hdr(uint8_t *restrict padd,
117 volatile struct mlx5_cqe *restrict cqe,
120 uint32_t mlx5_ptype_table[] __rte_cache_aligned = {
121 [0xff] = RTE_PTYPE_ALL_MASK, /* Last entry for errored packet. */
124 uint8_t mlx5_cksum_table[1 << 10] __rte_cache_aligned;
125 uint8_t mlx5_swp_types_table[1 << 10] __rte_cache_aligned;
128 * Build a table to translate Rx completion flags to packet type.
130 * @note: fix mlx5_dev_supported_ptypes_get() if any change here.
133 mlx5_set_ptype_table(void)
136 uint32_t (*p)[RTE_DIM(mlx5_ptype_table)] = &mlx5_ptype_table;
138 /* Last entry must not be overwritten, reserved for errored packet. */
139 for (i = 0; i < RTE_DIM(mlx5_ptype_table) - 1; ++i)
140 (*p)[i] = RTE_PTYPE_UNKNOWN;
142 * The index to the array should have:
143 * bit[1:0] = l3_hdr_type
144 * bit[4:2] = l4_hdr_type
147 * bit[7] = outer_l3_type
150 (*p)[0x00] = RTE_PTYPE_L2_ETHER;
152 (*p)[0x01] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
153 RTE_PTYPE_L4_NONFRAG;
154 (*p)[0x02] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
155 RTE_PTYPE_L4_NONFRAG;
157 (*p)[0x21] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
159 (*p)[0x22] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
162 (*p)[0x05] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
164 (*p)[0x06] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
166 (*p)[0x0d] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
168 (*p)[0x0e] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
170 (*p)[0x11] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
172 (*p)[0x12] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
175 (*p)[0x09] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
177 (*p)[0x0a] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
179 /* Repeat with outer_l3_type being set. Just in case. */
180 (*p)[0x81] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
181 RTE_PTYPE_L4_NONFRAG;
182 (*p)[0x82] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
183 RTE_PTYPE_L4_NONFRAG;
184 (*p)[0xa1] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
186 (*p)[0xa2] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
188 (*p)[0x85] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
190 (*p)[0x86] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
192 (*p)[0x8d] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
194 (*p)[0x8e] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
196 (*p)[0x91] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
198 (*p)[0x92] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
200 (*p)[0x89] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
202 (*p)[0x8a] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
205 (*p)[0x40] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN;
206 (*p)[0x41] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
207 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
208 RTE_PTYPE_INNER_L4_NONFRAG;
209 (*p)[0x42] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
210 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
211 RTE_PTYPE_INNER_L4_NONFRAG;
212 (*p)[0xc0] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN;
213 (*p)[0xc1] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
214 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
215 RTE_PTYPE_INNER_L4_NONFRAG;
216 (*p)[0xc2] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
217 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
218 RTE_PTYPE_INNER_L4_NONFRAG;
219 /* Tunneled - Fragmented */
220 (*p)[0x61] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
221 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
222 RTE_PTYPE_INNER_L4_FRAG;
223 (*p)[0x62] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
224 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
225 RTE_PTYPE_INNER_L4_FRAG;
226 (*p)[0xe1] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
227 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
228 RTE_PTYPE_INNER_L4_FRAG;
229 (*p)[0xe2] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
230 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
231 RTE_PTYPE_INNER_L4_FRAG;
233 (*p)[0x45] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
234 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
235 RTE_PTYPE_INNER_L4_TCP;
236 (*p)[0x46] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
237 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
238 RTE_PTYPE_INNER_L4_TCP;
239 (*p)[0x4d] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
240 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
241 RTE_PTYPE_INNER_L4_TCP;
242 (*p)[0x4e] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
243 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
244 RTE_PTYPE_INNER_L4_TCP;
245 (*p)[0x51] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
246 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
247 RTE_PTYPE_INNER_L4_TCP;
248 (*p)[0x52] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
249 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
250 RTE_PTYPE_INNER_L4_TCP;
251 (*p)[0xc5] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
252 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
253 RTE_PTYPE_INNER_L4_TCP;
254 (*p)[0xc6] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
255 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
256 RTE_PTYPE_INNER_L4_TCP;
257 (*p)[0xcd] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
258 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
259 RTE_PTYPE_INNER_L4_TCP;
260 (*p)[0xce] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
261 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
262 RTE_PTYPE_INNER_L4_TCP;
263 (*p)[0xd1] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
264 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
265 RTE_PTYPE_INNER_L4_TCP;
266 (*p)[0xd2] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
267 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
268 RTE_PTYPE_INNER_L4_TCP;
270 (*p)[0x49] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
271 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
272 RTE_PTYPE_INNER_L4_UDP;
273 (*p)[0x4a] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV4_EXT_UNKNOWN |
274 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
275 RTE_PTYPE_INNER_L4_UDP;
276 (*p)[0xc9] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
277 RTE_PTYPE_INNER_L3_IPV6_EXT_UNKNOWN |
278 RTE_PTYPE_INNER_L4_UDP;
279 (*p)[0xca] = RTE_PTYPE_L2_ETHER | RTE_PTYPE_L3_IPV6_EXT_UNKNOWN |
280 RTE_PTYPE_INNER_L3_IPV4_EXT_UNKNOWN |
281 RTE_PTYPE_INNER_L4_UDP;
285 * Build a table to translate packet to checksum type of Verbs.
288 mlx5_set_cksum_table(void)
294 * The index should have:
295 * bit[0] = PKT_TX_TCP_SEG
296 * bit[2:3] = PKT_TX_UDP_CKSUM, PKT_TX_TCP_CKSUM
297 * bit[4] = PKT_TX_IP_CKSUM
298 * bit[8] = PKT_TX_OUTER_IP_CKSUM
301 for (i = 0; i < RTE_DIM(mlx5_cksum_table); ++i) {
304 /* Tunneled packet. */
305 if (i & (1 << 8)) /* Outer IP. */
306 v |= MLX5_ETH_WQE_L3_CSUM;
307 if (i & (1 << 4)) /* Inner IP. */
308 v |= MLX5_ETH_WQE_L3_INNER_CSUM;
309 if (i & (3 << 2 | 1 << 0)) /* L4 or TSO. */
310 v |= MLX5_ETH_WQE_L4_INNER_CSUM;
313 if (i & (1 << 4)) /* IP. */
314 v |= MLX5_ETH_WQE_L3_CSUM;
315 if (i & (3 << 2 | 1 << 0)) /* L4 or TSO. */
316 v |= MLX5_ETH_WQE_L4_CSUM;
318 mlx5_cksum_table[i] = v;
323 * Build a table to translate packet type of mbuf to SWP type of Verbs.
326 mlx5_set_swp_types_table(void)
332 * The index should have:
333 * bit[0:1] = PKT_TX_L4_MASK
334 * bit[4] = PKT_TX_IPV6
335 * bit[8] = PKT_TX_OUTER_IPV6
336 * bit[9] = PKT_TX_OUTER_UDP
338 for (i = 0; i < RTE_DIM(mlx5_swp_types_table); ++i) {
341 v |= MLX5_ETH_WQE_L3_OUTER_IPV6;
343 v |= MLX5_ETH_WQE_L4_OUTER_UDP;
345 v |= MLX5_ETH_WQE_L3_INNER_IPV6;
346 if ((i & 3) == (PKT_TX_UDP_CKSUM >> 52))
347 v |= MLX5_ETH_WQE_L4_INNER_UDP;
348 mlx5_swp_types_table[i] = v;
353 * Set Software Parser flags and offsets in Ethernet Segment of WQE.
354 * Flags must be preliminary initialized to zero.
357 * Pointer to burst routine local context.
359 * Pointer to store Software Parser flags
361 * Configured Tx offloads mask. It is fully defined at
362 * compile time and may be used for optimization.
365 * Software Parser offsets packed in dword.
366 * Software Parser flags are set by pointer.
368 static __rte_always_inline uint32_t
369 txq_mbuf_to_swp(struct mlx5_txq_local *restrict loc,
374 unsigned int idx, off;
377 if (!MLX5_TXOFF_CONFIG(SWP))
379 ol = loc->mbuf->ol_flags;
380 tunnel = ol & PKT_TX_TUNNEL_MASK;
382 * Check whether Software Parser is required.
383 * Only customized tunnels may ask for.
385 if (likely(tunnel != PKT_TX_TUNNEL_UDP && tunnel != PKT_TX_TUNNEL_IP))
388 * The index should have:
389 * bit[0:1] = PKT_TX_L4_MASK
390 * bit[4] = PKT_TX_IPV6
391 * bit[8] = PKT_TX_OUTER_IPV6
392 * bit[9] = PKT_TX_OUTER_UDP
394 idx = (ol & (PKT_TX_L4_MASK | PKT_TX_IPV6 | PKT_TX_OUTER_IPV6)) >> 52;
395 idx |= (tunnel == PKT_TX_TUNNEL_UDP) ? (1 << 9) : 0;
396 *swp_flags = mlx5_swp_types_table[idx];
398 * Set offsets for SW parser. Since ConnectX-5, SW parser just
399 * complements HW parser. SW parser starts to engage only if HW parser
400 * can't reach a header. For the older devices, HW parser will not kick
401 * in if any of SWP offsets is set. Therefore, all of the L3 offsets
402 * should be set regardless of HW offload.
404 off = loc->mbuf->outer_l2_len;
405 if (MLX5_TXOFF_CONFIG(VLAN) && ol & PKT_TX_VLAN_PKT)
406 off += sizeof(struct rte_vlan_hdr);
407 set = (off >> 1) << 8; /* Outer L3 offset. */
408 off += loc->mbuf->outer_l3_len;
409 if (tunnel == PKT_TX_TUNNEL_UDP)
410 set |= off >> 1; /* Outer L4 offset. */
411 if (ol & (PKT_TX_IPV4 | PKT_TX_IPV6)) { /* Inner IP. */
412 const uint64_t csum = ol & PKT_TX_L4_MASK;
413 off += loc->mbuf->l2_len;
414 set |= (off >> 1) << 24; /* Inner L3 offset. */
415 if (csum == PKT_TX_TCP_CKSUM ||
416 csum == PKT_TX_UDP_CKSUM ||
417 (MLX5_TXOFF_CONFIG(TSO) && ol & PKT_TX_TCP_SEG)) {
418 off += loc->mbuf->l3_len;
419 set |= (off >> 1) << 16; /* Inner L4 offset. */
422 set = rte_cpu_to_le_32(set);
427 * Convert the Checksum offloads to Verbs.
430 * Pointer to the mbuf.
433 * Converted checksum flags.
435 static __rte_always_inline uint8_t
436 txq_ol_cksum_to_cs(struct rte_mbuf *buf)
439 uint8_t is_tunnel = !!(buf->ol_flags & PKT_TX_TUNNEL_MASK);
440 const uint64_t ol_flags_mask = PKT_TX_TCP_SEG | PKT_TX_L4_MASK |
441 PKT_TX_IP_CKSUM | PKT_TX_OUTER_IP_CKSUM;
444 * The index should have:
445 * bit[0] = PKT_TX_TCP_SEG
446 * bit[2:3] = PKT_TX_UDP_CKSUM, PKT_TX_TCP_CKSUM
447 * bit[4] = PKT_TX_IP_CKSUM
448 * bit[8] = PKT_TX_OUTER_IP_CKSUM
451 idx = ((buf->ol_flags & ol_flags_mask) >> 50) | (!!is_tunnel << 9);
452 return mlx5_cksum_table[idx];
456 * Internal function to compute the number of used descriptors in an RX queue
462 * The number of used rx descriptor.
465 rx_queue_count(struct mlx5_rxq_data *rxq)
467 struct rxq_zip *zip = &rxq->zip;
468 volatile struct mlx5_cqe *cqe;
469 const unsigned int cqe_n = (1 << rxq->cqe_n);
470 const unsigned int cqe_cnt = cqe_n - 1;
474 /* if we are processing a compressed cqe */
476 used = zip->cqe_cnt - zip->ca;
482 cqe = &(*rxq->cqes)[cq_ci & cqe_cnt];
483 while (check_cqe(cqe, cqe_n, cq_ci) != MLX5_CQE_STATUS_HW_OWN) {
487 op_own = cqe->op_own;
488 if (MLX5_CQE_FORMAT(op_own) == MLX5_COMPRESSED)
489 n = rte_be_to_cpu_32(cqe->byte_cnt);
494 cqe = &(*rxq->cqes)[cq_ci & cqe_cnt];
496 used = RTE_MIN(used, (1U << rxq->elts_n) - 1);
501 * DPDK callback to check the status of a rx descriptor.
506 * The index of the descriptor in the ring.
509 * The status of the tx descriptor.
512 mlx5_rx_descriptor_status(void *rx_queue, uint16_t offset)
514 struct mlx5_rxq_data *rxq = rx_queue;
515 struct mlx5_rxq_ctrl *rxq_ctrl =
516 container_of(rxq, struct mlx5_rxq_ctrl, rxq);
517 struct rte_eth_dev *dev = ETH_DEV(rxq_ctrl->priv);
519 if (dev->rx_pkt_burst != mlx5_rx_burst) {
523 if (offset >= (1 << rxq->elts_n)) {
527 if (offset < rx_queue_count(rxq))
528 return RTE_ETH_RX_DESC_DONE;
529 return RTE_ETH_RX_DESC_AVAIL;
533 * DPDK callback to get the number of used descriptors in a RX queue
536 * Pointer to the device structure.
542 * The number of used rx descriptor.
543 * -EINVAL if the queue is invalid
546 mlx5_rx_queue_count(struct rte_eth_dev *dev, uint16_t rx_queue_id)
548 struct mlx5_priv *priv = dev->data->dev_private;
549 struct mlx5_rxq_data *rxq;
551 if (dev->rx_pkt_burst != mlx5_rx_burst) {
555 rxq = (*priv->rxqs)[rx_queue_id];
560 return rx_queue_count(rxq);
563 #define MLX5_SYSTEM_LOG_DIR "/var/log"
565 * Dump debug information to log file.
570 * If not NULL this string is printed as a header to the output
571 * and the output will be in hexadecimal view.
573 * This is the buffer address to print out.
575 * The number of bytes to dump out.
578 mlx5_dump_debug_information(const char *fname, const char *hex_title,
579 const void *buf, unsigned int hex_len)
583 MKSTR(path, "%s/%s", MLX5_SYSTEM_LOG_DIR, fname);
584 fd = fopen(path, "a+");
586 DRV_LOG(WARNING, "cannot open %s for debug dump\n",
588 MKSTR(path2, "./%s", fname);
589 fd = fopen(path2, "a+");
591 DRV_LOG(ERR, "cannot open %s for debug dump\n",
595 DRV_LOG(INFO, "New debug dump in file %s\n", path2);
597 DRV_LOG(INFO, "New debug dump in file %s\n", path);
600 rte_hexdump(fd, hex_title, buf, hex_len);
602 fprintf(fd, "%s", (const char *)buf);
603 fprintf(fd, "\n\n\n");
608 * Move QP from error state to running state and initialize indexes.
611 * Pointer to TX queue control structure.
614 * 0 on success, else -1.
617 tx_recover_qp(struct mlx5_txq_ctrl *txq_ctrl)
619 struct mlx5_mp_arg_queue_state_modify sm = {
621 .queue_id = txq_ctrl->txq.idx,
624 if (mlx5_queue_state_modify(ETH_DEV(txq_ctrl->priv), &sm))
626 txq_ctrl->txq.wqe_ci = 0;
627 txq_ctrl->txq.wqe_pi = 0;
628 txq_ctrl->txq.elts_comp = 0;
632 /* Return 1 if the error CQE is signed otherwise, sign it and return 0. */
634 check_err_cqe_seen(volatile struct mlx5_err_cqe *err_cqe)
636 static const uint8_t magic[] = "seen";
640 for (i = 0; i < sizeof(magic); ++i)
641 if (!ret || err_cqe->rsvd1[i] != magic[i]) {
643 err_cqe->rsvd1[i] = magic[i];
652 * Pointer to TX queue structure.
654 * Pointer to the error CQE.
657 * Negative value if queue recovery failed,
658 * the last Tx buffer element to free otherwise.
661 mlx5_tx_error_cqe_handle(struct mlx5_txq_data *restrict txq,
662 volatile struct mlx5_err_cqe *err_cqe)
664 if (err_cqe->syndrome != MLX5_CQE_SYNDROME_WR_FLUSH_ERR) {
665 const uint16_t wqe_m = ((1 << txq->wqe_n) - 1);
666 struct mlx5_txq_ctrl *txq_ctrl =
667 container_of(txq, struct mlx5_txq_ctrl, txq);
668 uint16_t new_wqe_pi = rte_be_to_cpu_16(err_cqe->wqe_counter);
669 int seen = check_err_cqe_seen(err_cqe);
671 if (!seen && txq_ctrl->dump_file_n <
672 txq_ctrl->priv->config.max_dump_files_num) {
673 MKSTR(err_str, "Unexpected CQE error syndrome "
674 "0x%02x CQN = %u SQN = %u wqe_counter = %u "
675 "wq_ci = %u cq_ci = %u", err_cqe->syndrome,
676 txq->cqe_s, txq->qp_num_8s >> 8,
677 rte_be_to_cpu_16(err_cqe->wqe_counter),
678 txq->wqe_ci, txq->cq_ci);
679 MKSTR(name, "dpdk_mlx5_port_%u_txq_%u_index_%u_%u",
680 PORT_ID(txq_ctrl->priv), txq->idx,
681 txq_ctrl->dump_file_n, (uint32_t)rte_rdtsc());
682 mlx5_dump_debug_information(name, NULL, err_str, 0);
683 mlx5_dump_debug_information(name, "MLX5 Error CQ:",
684 (const void *)((uintptr_t)
688 mlx5_dump_debug_information(name, "MLX5 Error SQ:",
689 (const void *)((uintptr_t)
693 txq_ctrl->dump_file_n++;
697 * Count errors in WQEs units.
698 * Later it can be improved to count error packets,
699 * for example, by SQ parsing to find how much packets
700 * should be counted for each WQE.
702 txq->stats.oerrors += ((txq->wqe_ci & wqe_m) -
704 if (tx_recover_qp(txq_ctrl) == 0) {
706 /* Release all the remaining buffers. */
707 return txq->elts_head;
709 /* Recovering failed - try again later on the same WQE. */
714 /* Do not release buffers. */
715 return txq->elts_tail;
719 * Translate RX completion flags to packet type.
722 * Pointer to RX queue structure.
726 * @note: fix mlx5_dev_supported_ptypes_get() if any change here.
729 * Packet type for struct rte_mbuf.
731 static inline uint32_t
732 rxq_cq_to_pkt_type(struct mlx5_rxq_data *rxq, volatile struct mlx5_cqe *cqe)
735 uint8_t pinfo = cqe->pkt_info;
736 uint16_t ptype = cqe->hdr_type_etc;
739 * The index to the array should have:
740 * bit[1:0] = l3_hdr_type
741 * bit[4:2] = l4_hdr_type
744 * bit[7] = outer_l3_type
746 idx = ((pinfo & 0x3) << 6) | ((ptype & 0xfc00) >> 10);
747 return mlx5_ptype_table[idx] | rxq->tunnel * !!(idx & (1 << 6));
751 * Initialize Rx WQ and indexes.
754 * Pointer to RX queue structure.
757 mlx5_rxq_initialize(struct mlx5_rxq_data *rxq)
759 const unsigned int wqe_n = 1 << rxq->elts_n;
762 for (i = 0; (i != wqe_n); ++i) {
763 volatile struct mlx5_wqe_data_seg *scat;
767 if (mlx5_rxq_mprq_enabled(rxq)) {
768 struct mlx5_mprq_buf *buf = (*rxq->mprq_bufs)[i];
770 scat = &((volatile struct mlx5_wqe_mprq *)
772 addr = (uintptr_t)mlx5_mprq_buf_addr(buf,
773 1 << rxq->strd_num_n);
774 byte_count = (1 << rxq->strd_sz_n) *
775 (1 << rxq->strd_num_n);
777 struct rte_mbuf *buf = (*rxq->elts)[i];
779 scat = &((volatile struct mlx5_wqe_data_seg *)
781 addr = rte_pktmbuf_mtod(buf, uintptr_t);
782 byte_count = DATA_LEN(buf);
784 /* scat->addr must be able to store a pointer. */
785 assert(sizeof(scat->addr) >= sizeof(uintptr_t));
786 *scat = (struct mlx5_wqe_data_seg){
787 .addr = rte_cpu_to_be_64(addr),
788 .byte_count = rte_cpu_to_be_32(byte_count),
789 .lkey = mlx5_rx_addr2mr(rxq, addr),
792 rxq->consumed_strd = 0;
793 rxq->decompressed = 0;
795 rxq->zip = (struct rxq_zip){
798 /* Update doorbell counter. */
799 rxq->rq_ci = wqe_n >> rxq->sges_n;
801 *rxq->rq_db = rte_cpu_to_be_32(rxq->rq_ci);
805 * Modify a Verbs/DevX queue state.
806 * This must be called from the primary process.
809 * Pointer to Ethernet device.
811 * State modify request parameters.
814 * 0 in case of success else non-zero value and rte_errno is set.
817 mlx5_queue_state_modify_primary(struct rte_eth_dev *dev,
818 const struct mlx5_mp_arg_queue_state_modify *sm)
821 struct mlx5_priv *priv = dev->data->dev_private;
824 struct mlx5_rxq_data *rxq = (*priv->rxqs)[sm->queue_id];
825 struct mlx5_rxq_ctrl *rxq_ctrl =
826 container_of(rxq, struct mlx5_rxq_ctrl, rxq);
828 if (rxq_ctrl->obj->type == MLX5_RXQ_OBJ_TYPE_IBV) {
829 struct ibv_wq_attr mod = {
830 .attr_mask = IBV_WQ_ATTR_STATE,
831 .wq_state = sm->state,
834 ret = mlx5_glue->modify_wq(rxq_ctrl->obj->wq, &mod);
835 } else { /* rxq_ctrl->obj->type == MLX5_RXQ_OBJ_TYPE_DEVX_RQ. */
836 struct mlx5_devx_modify_rq_attr rq_attr;
838 memset(&rq_attr, 0, sizeof(rq_attr));
839 if (sm->state == IBV_WQS_RESET) {
840 rq_attr.rq_state = MLX5_RQC_STATE_ERR;
841 rq_attr.state = MLX5_RQC_STATE_RST;
842 } else if (sm->state == IBV_WQS_RDY) {
843 rq_attr.rq_state = MLX5_RQC_STATE_RST;
844 rq_attr.state = MLX5_RQC_STATE_RDY;
845 } else if (sm->state == IBV_WQS_ERR) {
846 rq_attr.rq_state = MLX5_RQC_STATE_RDY;
847 rq_attr.state = MLX5_RQC_STATE_ERR;
849 ret = mlx5_devx_cmd_modify_rq(rxq_ctrl->obj->rq,
853 DRV_LOG(ERR, "Cannot change Rx WQ state to %u - %s\n",
854 sm->state, strerror(errno));
859 struct mlx5_txq_data *txq = (*priv->txqs)[sm->queue_id];
860 struct mlx5_txq_ctrl *txq_ctrl =
861 container_of(txq, struct mlx5_txq_ctrl, txq);
862 struct ibv_qp_attr mod = {
863 .qp_state = IBV_QPS_RESET,
864 .port_num = (uint8_t)priv->ibv_port,
866 struct ibv_qp *qp = txq_ctrl->ibv->qp;
868 ret = mlx5_glue->modify_qp(qp, &mod, IBV_QP_STATE);
870 DRV_LOG(ERR, "Cannot change the Tx QP state to RESET "
871 "%s\n", strerror(errno));
875 mod.qp_state = IBV_QPS_INIT;
876 ret = mlx5_glue->modify_qp(qp, &mod,
877 (IBV_QP_STATE | IBV_QP_PORT));
879 DRV_LOG(ERR, "Cannot change Tx QP state to INIT %s\n",
884 mod.qp_state = IBV_QPS_RTR;
885 ret = mlx5_glue->modify_qp(qp, &mod, IBV_QP_STATE);
887 DRV_LOG(ERR, "Cannot change Tx QP state to RTR %s\n",
892 mod.qp_state = IBV_QPS_RTS;
893 ret = mlx5_glue->modify_qp(qp, &mod, IBV_QP_STATE);
895 DRV_LOG(ERR, "Cannot change Tx QP state to RTS %s\n",
905 * Modify a Verbs queue state.
908 * Pointer to Ethernet device.
910 * State modify request parameters.
913 * 0 in case of success else non-zero value.
916 mlx5_queue_state_modify(struct rte_eth_dev *dev,
917 struct mlx5_mp_arg_queue_state_modify *sm)
921 switch (rte_eal_process_type()) {
922 case RTE_PROC_PRIMARY:
923 ret = mlx5_queue_state_modify_primary(dev, sm);
925 case RTE_PROC_SECONDARY:
926 ret = mlx5_mp_req_queue_state_modify(dev, sm);
936 * The function inserts the RQ state to reset when the first error CQE is
937 * shown, then drains the CQ by the caller function loop. When the CQ is empty,
938 * it moves the RQ state to ready and initializes the RQ.
939 * Next CQE identification and error counting are in the caller responsibility.
942 * Pointer to RX queue structure.
943 * @param[in] mbuf_prepare
944 * Whether to prepare mbufs for the RQ.
947 * -1 in case of recovery error, otherwise the CQE status.
950 mlx5_rx_err_handle(struct mlx5_rxq_data *rxq, uint8_t mbuf_prepare)
952 const uint16_t cqe_n = 1 << rxq->cqe_n;
953 const uint16_t cqe_mask = cqe_n - 1;
954 const unsigned int wqe_n = 1 << rxq->elts_n;
955 struct mlx5_rxq_ctrl *rxq_ctrl =
956 container_of(rxq, struct mlx5_rxq_ctrl, rxq);
958 volatile struct mlx5_cqe *cqe;
959 volatile struct mlx5_err_cqe *err_cqe;
961 .cqe = &(*rxq->cqes)[rxq->cq_ci & cqe_mask],
963 struct mlx5_mp_arg_queue_state_modify sm;
966 switch (rxq->err_state) {
967 case MLX5_RXQ_ERR_STATE_NO_ERROR:
968 rxq->err_state = MLX5_RXQ_ERR_STATE_NEED_RESET;
970 case MLX5_RXQ_ERR_STATE_NEED_RESET:
972 sm.queue_id = rxq->idx;
973 sm.state = IBV_WQS_RESET;
974 if (mlx5_queue_state_modify(ETH_DEV(rxq_ctrl->priv), &sm))
976 if (rxq_ctrl->dump_file_n <
977 rxq_ctrl->priv->config.max_dump_files_num) {
978 MKSTR(err_str, "Unexpected CQE error syndrome "
979 "0x%02x CQN = %u RQN = %u wqe_counter = %u"
980 " rq_ci = %u cq_ci = %u", u.err_cqe->syndrome,
981 rxq->cqn, rxq_ctrl->wqn,
982 rte_be_to_cpu_16(u.err_cqe->wqe_counter),
983 rxq->rq_ci << rxq->sges_n, rxq->cq_ci);
984 MKSTR(name, "dpdk_mlx5_port_%u_rxq_%u_%u",
985 rxq->port_id, rxq->idx, (uint32_t)rte_rdtsc());
986 mlx5_dump_debug_information(name, NULL, err_str, 0);
987 mlx5_dump_debug_information(name, "MLX5 Error CQ:",
988 (const void *)((uintptr_t)
990 sizeof(*u.cqe) * cqe_n);
991 mlx5_dump_debug_information(name, "MLX5 Error RQ:",
992 (const void *)((uintptr_t)
995 rxq_ctrl->dump_file_n++;
997 rxq->err_state = MLX5_RXQ_ERR_STATE_NEED_READY;
999 case MLX5_RXQ_ERR_STATE_NEED_READY:
1000 ret = check_cqe(u.cqe, cqe_n, rxq->cq_ci);
1001 if (ret == MLX5_CQE_STATUS_HW_OWN) {
1003 *rxq->cq_db = rte_cpu_to_be_32(rxq->cq_ci);
1006 * The RQ consumer index must be zeroed while moving
1007 * from RESET state to RDY state.
1009 *rxq->rq_db = rte_cpu_to_be_32(0);
1012 sm.queue_id = rxq->idx;
1013 sm.state = IBV_WQS_RDY;
1014 if (mlx5_queue_state_modify(ETH_DEV(rxq_ctrl->priv),
1018 const uint16_t q_mask = wqe_n - 1;
1020 struct rte_mbuf **elt;
1022 unsigned int n = wqe_n - (rxq->rq_ci -
1025 for (i = 0; i < (int)n; ++i) {
1026 elt_idx = (rxq->rq_ci + i) & q_mask;
1027 elt = &(*rxq->elts)[elt_idx];
1028 *elt = rte_mbuf_raw_alloc(rxq->mp);
1030 for (i--; i >= 0; --i) {
1031 elt_idx = (rxq->rq_ci +
1035 rte_pktmbuf_free_seg
1042 mlx5_rxq_initialize(rxq);
1043 rxq->err_state = MLX5_RXQ_ERR_STATE_NO_ERROR;
1052 * Get size of the next packet for a given CQE. For compressed CQEs, the
1053 * consumer index is updated only once all packets of the current one have
1057 * Pointer to RX queue.
1061 * Store pointer to mini-CQE if compressed. Otherwise, the pointer is not
1065 * 0 in case of empty CQE, otherwise the packet size in bytes.
1068 mlx5_rx_poll_len(struct mlx5_rxq_data *rxq, volatile struct mlx5_cqe *cqe,
1069 uint16_t cqe_cnt, volatile struct mlx5_mini_cqe8 **mcqe)
1071 struct rxq_zip *zip = &rxq->zip;
1072 uint16_t cqe_n = cqe_cnt + 1;
1078 /* Process compressed data in the CQE and mini arrays. */
1080 volatile struct mlx5_mini_cqe8 (*mc)[8] =
1081 (volatile struct mlx5_mini_cqe8 (*)[8])
1082 (uintptr_t)(&(*rxq->cqes)[zip->ca &
1085 len = rte_be_to_cpu_32((*mc)[zip->ai & 7].byte_cnt);
1086 *mcqe = &(*mc)[zip->ai & 7];
1087 if ((++zip->ai & 7) == 0) {
1088 /* Invalidate consumed CQEs */
1091 while (idx != end) {
1092 (*rxq->cqes)[idx & cqe_cnt].op_own =
1093 MLX5_CQE_INVALIDATE;
1097 * Increment consumer index to skip the number
1098 * of CQEs consumed. Hardware leaves holes in
1099 * the CQ ring for software use.
1104 if (unlikely(rxq->zip.ai == rxq->zip.cqe_cnt)) {
1105 /* Invalidate the rest */
1109 while (idx != end) {
1110 (*rxq->cqes)[idx & cqe_cnt].op_own =
1111 MLX5_CQE_INVALIDATE;
1114 rxq->cq_ci = zip->cq_ci;
1118 * No compressed data, get next CQE and verify if it is
1125 ret = check_cqe(cqe, cqe_n, rxq->cq_ci);
1126 if (unlikely(ret != MLX5_CQE_STATUS_SW_OWN)) {
1127 if (unlikely(ret == MLX5_CQE_STATUS_ERR ||
1129 ret = mlx5_rx_err_handle(rxq, 0);
1130 if (ret == MLX5_CQE_STATUS_HW_OWN ||
1138 op_own = cqe->op_own;
1139 if (MLX5_CQE_FORMAT(op_own) == MLX5_COMPRESSED) {
1140 volatile struct mlx5_mini_cqe8 (*mc)[8] =
1141 (volatile struct mlx5_mini_cqe8 (*)[8])
1142 (uintptr_t)(&(*rxq->cqes)
1146 /* Fix endianness. */
1147 zip->cqe_cnt = rte_be_to_cpu_32(cqe->byte_cnt);
1149 * Current mini array position is the one
1150 * returned by check_cqe64().
1152 * If completion comprises several mini arrays,
1153 * as a special case the second one is located
1154 * 7 CQEs after the initial CQE instead of 8
1155 * for subsequent ones.
1157 zip->ca = rxq->cq_ci;
1158 zip->na = zip->ca + 7;
1159 /* Compute the next non compressed CQE. */
1161 zip->cq_ci = rxq->cq_ci + zip->cqe_cnt;
1162 /* Get packet size to return. */
1163 len = rte_be_to_cpu_32((*mc)[0].byte_cnt);
1166 /* Prefetch all to be invalidated */
1169 while (idx != end) {
1170 rte_prefetch0(&(*rxq->cqes)[(idx) &
1175 len = rte_be_to_cpu_32(cqe->byte_cnt);
1178 if (unlikely(rxq->err_state)) {
1179 cqe = &(*rxq->cqes)[rxq->cq_ci & cqe_cnt];
1180 ++rxq->stats.idropped;
1188 * Translate RX completion flags to offload flags.
1194 * Offload flags (ol_flags) for struct rte_mbuf.
1196 static inline uint32_t
1197 rxq_cq_to_ol_flags(volatile struct mlx5_cqe *cqe)
1199 uint32_t ol_flags = 0;
1200 uint16_t flags = rte_be_to_cpu_16(cqe->hdr_type_etc);
1204 MLX5_CQE_RX_L3_HDR_VALID,
1205 PKT_RX_IP_CKSUM_GOOD) |
1207 MLX5_CQE_RX_L4_HDR_VALID,
1208 PKT_RX_L4_CKSUM_GOOD);
1213 * Fill in mbuf fields from RX completion flags.
1214 * Note that pkt->ol_flags should be initialized outside of this function.
1217 * Pointer to RX queue.
1222 * @param rss_hash_res
1223 * Packet RSS Hash result.
1226 rxq_cq_to_mbuf(struct mlx5_rxq_data *rxq, struct rte_mbuf *pkt,
1227 volatile struct mlx5_cqe *cqe, uint32_t rss_hash_res)
1229 /* Update packet information. */
1230 pkt->packet_type = rxq_cq_to_pkt_type(rxq, cqe);
1231 if (rss_hash_res && rxq->rss_hash) {
1232 pkt->hash.rss = rss_hash_res;
1233 pkt->ol_flags |= PKT_RX_RSS_HASH;
1235 if (rxq->mark && MLX5_FLOW_MARK_IS_VALID(cqe->sop_drop_qpn)) {
1236 pkt->ol_flags |= PKT_RX_FDIR;
1237 if (cqe->sop_drop_qpn !=
1238 rte_cpu_to_be_32(MLX5_FLOW_MARK_DEFAULT)) {
1239 uint32_t mark = cqe->sop_drop_qpn;
1241 pkt->ol_flags |= PKT_RX_FDIR_ID;
1242 pkt->hash.fdir.hi = mlx5_flow_mark_get(mark);
1246 pkt->ol_flags |= rxq_cq_to_ol_flags(cqe);
1247 if (rxq->vlan_strip &&
1248 (cqe->hdr_type_etc & rte_cpu_to_be_16(MLX5_CQE_VLAN_STRIPPED))) {
1249 pkt->ol_flags |= PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED;
1250 pkt->vlan_tci = rte_be_to_cpu_16(cqe->vlan_info);
1252 if (rxq->hw_timestamp) {
1253 pkt->timestamp = rte_be_to_cpu_64(cqe->timestamp);
1254 pkt->ol_flags |= PKT_RX_TIMESTAMP;
1259 * DPDK callback for RX.
1262 * Generic pointer to RX queue structure.
1264 * Array to store received packets.
1266 * Maximum number of packets in array.
1269 * Number of packets successfully received (<= pkts_n).
1272 mlx5_rx_burst(void *dpdk_rxq, struct rte_mbuf **pkts, uint16_t pkts_n)
1274 struct mlx5_rxq_data *rxq = dpdk_rxq;
1275 const unsigned int wqe_cnt = (1 << rxq->elts_n) - 1;
1276 const unsigned int cqe_cnt = (1 << rxq->cqe_n) - 1;
1277 const unsigned int sges_n = rxq->sges_n;
1278 struct rte_mbuf *pkt = NULL;
1279 struct rte_mbuf *seg = NULL;
1280 volatile struct mlx5_cqe *cqe =
1281 &(*rxq->cqes)[rxq->cq_ci & cqe_cnt];
1283 unsigned int rq_ci = rxq->rq_ci << sges_n;
1284 int len = 0; /* keep its value across iterations. */
1287 unsigned int idx = rq_ci & wqe_cnt;
1288 volatile struct mlx5_wqe_data_seg *wqe =
1289 &((volatile struct mlx5_wqe_data_seg *)rxq->wqes)[idx];
1290 struct rte_mbuf *rep = (*rxq->elts)[idx];
1291 volatile struct mlx5_mini_cqe8 *mcqe = NULL;
1292 uint32_t rss_hash_res;
1300 rep = rte_mbuf_raw_alloc(rxq->mp);
1301 if (unlikely(rep == NULL)) {
1302 ++rxq->stats.rx_nombuf;
1305 * no buffers before we even started,
1306 * bail out silently.
1310 while (pkt != seg) {
1311 assert(pkt != (*rxq->elts)[idx]);
1315 rte_mbuf_raw_free(pkt);
1321 cqe = &(*rxq->cqes)[rxq->cq_ci & cqe_cnt];
1322 len = mlx5_rx_poll_len(rxq, cqe, cqe_cnt, &mcqe);
1324 rte_mbuf_raw_free(rep);
1328 assert(len >= (rxq->crc_present << 2));
1330 /* If compressed, take hash result from mini-CQE. */
1331 rss_hash_res = rte_be_to_cpu_32(mcqe == NULL ?
1333 mcqe->rx_hash_result);
1334 rxq_cq_to_mbuf(rxq, pkt, cqe, rss_hash_res);
1335 if (rxq->crc_present)
1336 len -= RTE_ETHER_CRC_LEN;
1338 if (cqe->lro_num_seg > 1) {
1340 (rte_pktmbuf_mtod(pkt, uint8_t *), cqe,
1342 pkt->ol_flags |= PKT_RX_LRO;
1343 pkt->tso_segsz = len / cqe->lro_num_seg;
1346 DATA_LEN(rep) = DATA_LEN(seg);
1347 PKT_LEN(rep) = PKT_LEN(seg);
1348 SET_DATA_OFF(rep, DATA_OFF(seg));
1349 PORT(rep) = PORT(seg);
1350 (*rxq->elts)[idx] = rep;
1352 * Fill NIC descriptor with the new buffer. The lkey and size
1353 * of the buffers are already known, only the buffer address
1356 wqe->addr = rte_cpu_to_be_64(rte_pktmbuf_mtod(rep, uintptr_t));
1357 /* If there's only one MR, no need to replace LKey in WQE. */
1358 if (unlikely(mlx5_mr_btree_len(&rxq->mr_ctrl.cache_bh) > 1))
1359 wqe->lkey = mlx5_rx_mb2mr(rxq, rep);
1360 if (len > DATA_LEN(seg)) {
1361 len -= DATA_LEN(seg);
1366 DATA_LEN(seg) = len;
1367 #ifdef MLX5_PMD_SOFT_COUNTERS
1368 /* Increment bytes counter. */
1369 rxq->stats.ibytes += PKT_LEN(pkt);
1371 /* Return packet. */
1376 /* Align consumer index to the next stride. */
1381 if (unlikely((i == 0) && ((rq_ci >> sges_n) == rxq->rq_ci)))
1383 /* Update the consumer index. */
1384 rxq->rq_ci = rq_ci >> sges_n;
1386 *rxq->cq_db = rte_cpu_to_be_32(rxq->cq_ci);
1388 *rxq->rq_db = rte_cpu_to_be_32(rxq->rq_ci);
1389 #ifdef MLX5_PMD_SOFT_COUNTERS
1390 /* Increment packets counter. */
1391 rxq->stats.ipackets += i;
1397 * Update LRO packet TCP header.
1398 * The HW LRO feature doesn't update the TCP header after coalescing the
1399 * TCP segments but supplies information in CQE to fill it by SW.
1402 * Pointer to the TCP header.
1404 * Pointer to the completion entry..
1406 * The L3 pseudo-header checksum.
1409 mlx5_lro_update_tcp_hdr(struct rte_tcp_hdr *restrict tcp,
1410 volatile struct mlx5_cqe *restrict cqe,
1413 uint8_t l4_type = (rte_be_to_cpu_16(cqe->hdr_type_etc) &
1414 MLX5_CQE_L4_TYPE_MASK) >> MLX5_CQE_L4_TYPE_SHIFT;
1416 * The HW calculates only the TCP payload checksum, need to complete
1417 * the TCP header checksum and the L3 pseudo-header checksum.
1419 uint32_t csum = phcsum + cqe->csum;
1421 if (l4_type == MLX5_L4_HDR_TYPE_TCP_EMPTY_ACK ||
1422 l4_type == MLX5_L4_HDR_TYPE_TCP_WITH_ACL) {
1423 tcp->tcp_flags |= RTE_TCP_ACK_FLAG;
1424 tcp->recv_ack = cqe->lro_ack_seq_num;
1425 tcp->rx_win = cqe->lro_tcp_win;
1427 if (cqe->lro_tcppsh_abort_dupack & MLX5_CQE_LRO_PUSH_MASK)
1428 tcp->tcp_flags |= RTE_TCP_PSH_FLAG;
1430 csum += rte_raw_cksum(tcp, (tcp->data_off & 0xF) * 4);
1431 csum = ((csum & 0xffff0000) >> 16) + (csum & 0xffff);
1432 csum = (~csum) & 0xffff;
1439 * Update LRO packet headers.
1440 * The HW LRO feature doesn't update the L3/TCP headers after coalescing the
1441 * TCP segments but supply information in CQE to fill it by SW.
1444 * The packet address.
1446 * Pointer to the completion entry..
1448 * The packet length.
1451 mlx5_lro_update_hdr(uint8_t *restrict padd,
1452 volatile struct mlx5_cqe *restrict cqe,
1456 struct rte_ether_hdr *eth;
1457 struct rte_vlan_hdr *vlan;
1458 struct rte_ipv4_hdr *ipv4;
1459 struct rte_ipv6_hdr *ipv6;
1460 struct rte_tcp_hdr *tcp;
1465 uint16_t proto = h.eth->ether_type;
1469 while (proto == RTE_BE16(RTE_ETHER_TYPE_VLAN) ||
1470 proto == RTE_BE16(RTE_ETHER_TYPE_QINQ)) {
1471 proto = h.vlan->eth_proto;
1474 if (proto == RTE_BE16(RTE_ETHER_TYPE_IPV4)) {
1475 h.ipv4->time_to_live = cqe->lro_min_ttl;
1476 h.ipv4->total_length = rte_cpu_to_be_16(len - (h.hdr - padd));
1477 h.ipv4->hdr_checksum = 0;
1478 h.ipv4->hdr_checksum = rte_ipv4_cksum(h.ipv4);
1479 phcsum = rte_ipv4_phdr_cksum(h.ipv4, 0);
1482 h.ipv6->hop_limits = cqe->lro_min_ttl;
1483 h.ipv6->payload_len = rte_cpu_to_be_16(len - (h.hdr - padd) -
1485 phcsum = rte_ipv6_phdr_cksum(h.ipv6, 0);
1488 mlx5_lro_update_tcp_hdr(h.tcp, cqe, phcsum);
1492 mlx5_mprq_buf_free_cb(void *addr __rte_unused, void *opaque)
1494 struct mlx5_mprq_buf *buf = opaque;
1496 if (rte_atomic16_read(&buf->refcnt) == 1) {
1497 rte_mempool_put(buf->mp, buf);
1498 } else if (rte_atomic16_add_return(&buf->refcnt, -1) == 0) {
1499 rte_atomic16_set(&buf->refcnt, 1);
1500 rte_mempool_put(buf->mp, buf);
1505 mlx5_mprq_buf_free(struct mlx5_mprq_buf *buf)
1507 mlx5_mprq_buf_free_cb(NULL, buf);
1511 mprq_buf_replace(struct mlx5_rxq_data *rxq, uint16_t rq_idx,
1512 const unsigned int strd_n)
1514 struct mlx5_mprq_buf *rep = rxq->mprq_repl;
1515 volatile struct mlx5_wqe_data_seg *wqe =
1516 &((volatile struct mlx5_wqe_mprq *)rxq->wqes)[rq_idx].dseg;
1519 assert(rep != NULL);
1520 /* Replace MPRQ buf. */
1521 (*rxq->mprq_bufs)[rq_idx] = rep;
1523 addr = mlx5_mprq_buf_addr(rep, strd_n);
1524 wqe->addr = rte_cpu_to_be_64((uintptr_t)addr);
1525 /* If there's only one MR, no need to replace LKey in WQE. */
1526 if (unlikely(mlx5_mr_btree_len(&rxq->mr_ctrl.cache_bh) > 1))
1527 wqe->lkey = mlx5_rx_addr2mr(rxq, (uintptr_t)addr);
1528 /* Stash a mbuf for next replacement. */
1529 if (likely(!rte_mempool_get(rxq->mprq_mp, (void **)&rep)))
1530 rxq->mprq_repl = rep;
1532 rxq->mprq_repl = NULL;
1536 * DPDK callback for RX with Multi-Packet RQ support.
1539 * Generic pointer to RX queue structure.
1541 * Array to store received packets.
1543 * Maximum number of packets in array.
1546 * Number of packets successfully received (<= pkts_n).
1549 mlx5_rx_burst_mprq(void *dpdk_rxq, struct rte_mbuf **pkts, uint16_t pkts_n)
1551 struct mlx5_rxq_data *rxq = dpdk_rxq;
1552 const unsigned int strd_n = 1 << rxq->strd_num_n;
1553 const unsigned int strd_sz = 1 << rxq->strd_sz_n;
1554 const unsigned int strd_shift =
1555 MLX5_MPRQ_STRIDE_SHIFT_BYTE * rxq->strd_shift_en;
1556 const unsigned int cq_mask = (1 << rxq->cqe_n) - 1;
1557 const unsigned int wq_mask = (1 << rxq->elts_n) - 1;
1558 volatile struct mlx5_cqe *cqe = &(*rxq->cqes)[rxq->cq_ci & cq_mask];
1560 uint32_t rq_ci = rxq->rq_ci;
1561 uint16_t consumed_strd = rxq->consumed_strd;
1562 uint16_t headroom_sz = rxq->strd_headroom_en * RTE_PKTMBUF_HEADROOM;
1563 struct mlx5_mprq_buf *buf = (*rxq->mprq_bufs)[rq_ci & wq_mask];
1565 while (i < pkts_n) {
1566 struct rte_mbuf *pkt;
1574 volatile struct mlx5_mini_cqe8 *mcqe = NULL;
1575 uint32_t rss_hash_res = 0;
1576 uint8_t lro_num_seg;
1578 if (consumed_strd == strd_n) {
1579 /* Replace WQE only if the buffer is still in use. */
1580 if (rte_atomic16_read(&buf->refcnt) > 1) {
1581 mprq_buf_replace(rxq, rq_ci & wq_mask, strd_n);
1582 /* Release the old buffer. */
1583 mlx5_mprq_buf_free(buf);
1584 } else if (unlikely(rxq->mprq_repl == NULL)) {
1585 struct mlx5_mprq_buf *rep;
1588 * Currently, the MPRQ mempool is out of buffer
1589 * and doing memcpy regardless of the size of Rx
1590 * packet. Retry allocation to get back to
1593 if (!rte_mempool_get(rxq->mprq_mp,
1595 rxq->mprq_repl = rep;
1597 /* Advance to the next WQE. */
1600 buf = (*rxq->mprq_bufs)[rq_ci & wq_mask];
1602 cqe = &(*rxq->cqes)[rxq->cq_ci & cq_mask];
1603 ret = mlx5_rx_poll_len(rxq, cqe, cq_mask, &mcqe);
1607 strd_cnt = (byte_cnt & MLX5_MPRQ_STRIDE_NUM_MASK) >>
1608 MLX5_MPRQ_STRIDE_NUM_SHIFT;
1610 consumed_strd += strd_cnt;
1611 if (byte_cnt & MLX5_MPRQ_FILLER_MASK)
1614 rss_hash_res = rte_be_to_cpu_32(cqe->rx_hash_res);
1615 strd_idx = rte_be_to_cpu_16(cqe->wqe_counter);
1617 /* mini-CQE for MPRQ doesn't have hash result. */
1618 strd_idx = rte_be_to_cpu_16(mcqe->stride_idx);
1620 assert(strd_idx < strd_n);
1621 assert(!((rte_be_to_cpu_16(cqe->wqe_id) ^ rq_ci) & wq_mask));
1622 lro_num_seg = cqe->lro_num_seg;
1624 * Currently configured to receive a packet per a stride. But if
1625 * MTU is adjusted through kernel interface, device could
1626 * consume multiple strides without raising an error. In this
1627 * case, the packet should be dropped because it is bigger than
1628 * the max_rx_pkt_len.
1630 if (unlikely(!lro_num_seg && strd_cnt > 1)) {
1631 ++rxq->stats.idropped;
1634 pkt = rte_pktmbuf_alloc(rxq->mp);
1635 if (unlikely(pkt == NULL)) {
1636 ++rxq->stats.rx_nombuf;
1639 len = (byte_cnt & MLX5_MPRQ_LEN_MASK) >> MLX5_MPRQ_LEN_SHIFT;
1640 assert((int)len >= (rxq->crc_present << 2));
1641 if (rxq->crc_present)
1642 len -= RTE_ETHER_CRC_LEN;
1643 offset = strd_idx * strd_sz + strd_shift;
1644 addr = RTE_PTR_ADD(mlx5_mprq_buf_addr(buf, strd_n), offset);
1646 * Memcpy packets to the target mbuf if:
1647 * - The size of packet is smaller than mprq_max_memcpy_len.
1648 * - Out of buffer in the Mempool for Multi-Packet RQ.
1650 if (len <= rxq->mprq_max_memcpy_len || rxq->mprq_repl == NULL) {
1652 * When memcpy'ing packet due to out-of-buffer, the
1653 * packet must be smaller than the target mbuf.
1655 if (unlikely(rte_pktmbuf_tailroom(pkt) < len)) {
1656 rte_pktmbuf_free_seg(pkt);
1657 ++rxq->stats.idropped;
1660 rte_memcpy(rte_pktmbuf_mtod(pkt, void *), addr, len);
1661 DATA_LEN(pkt) = len;
1663 rte_iova_t buf_iova;
1664 struct rte_mbuf_ext_shared_info *shinfo;
1665 uint16_t buf_len = strd_cnt * strd_sz;
1668 /* Increment the refcnt of the whole chunk. */
1669 rte_atomic16_add_return(&buf->refcnt, 1);
1670 assert((uint16_t)rte_atomic16_read(&buf->refcnt) <=
1672 buf_addr = RTE_PTR_SUB(addr, headroom_sz);
1674 * MLX5 device doesn't use iova but it is necessary in a
1675 * case where the Rx packet is transmitted via a
1678 buf_iova = rte_mempool_virt2iova(buf) +
1679 RTE_PTR_DIFF(buf_addr, buf);
1680 shinfo = &buf->shinfos[strd_idx];
1681 rte_mbuf_ext_refcnt_set(shinfo, 1);
1683 * EXT_ATTACHED_MBUF will be set to pkt->ol_flags when
1684 * attaching the stride to mbuf and more offload flags
1685 * will be added below by calling rxq_cq_to_mbuf().
1686 * Other fields will be overwritten.
1688 rte_pktmbuf_attach_extbuf(pkt, buf_addr, buf_iova,
1690 /* Set mbuf head-room. */
1691 pkt->data_off = headroom_sz;
1692 assert(pkt->ol_flags == EXT_ATTACHED_MBUF);
1694 * Prevent potential overflow due to MTU change through
1697 if (unlikely(rte_pktmbuf_tailroom(pkt) < len)) {
1698 rte_pktmbuf_free_seg(pkt);
1699 ++rxq->stats.idropped;
1702 DATA_LEN(pkt) = len;
1704 * LRO packet may consume all the stride memory, in this
1705 * case packet head-room space is not guaranteed so must
1706 * to add an empty mbuf for the head-room.
1708 if (!rxq->strd_headroom_en) {
1709 struct rte_mbuf *headroom_mbuf =
1710 rte_pktmbuf_alloc(rxq->mp);
1712 if (unlikely(headroom_mbuf == NULL)) {
1713 rte_pktmbuf_free_seg(pkt);
1714 ++rxq->stats.rx_nombuf;
1717 PORT(pkt) = rxq->port_id;
1718 NEXT(headroom_mbuf) = pkt;
1719 pkt = headroom_mbuf;
1723 rxq_cq_to_mbuf(rxq, pkt, cqe, rss_hash_res);
1724 if (lro_num_seg > 1) {
1725 mlx5_lro_update_hdr(addr, cqe, len);
1726 pkt->ol_flags |= PKT_RX_LRO;
1727 pkt->tso_segsz = strd_sz;
1730 PORT(pkt) = rxq->port_id;
1731 #ifdef MLX5_PMD_SOFT_COUNTERS
1732 /* Increment bytes counter. */
1733 rxq->stats.ibytes += PKT_LEN(pkt);
1735 /* Return packet. */
1739 /* Update the consumer indexes. */
1740 rxq->consumed_strd = consumed_strd;
1742 *rxq->cq_db = rte_cpu_to_be_32(rxq->cq_ci);
1743 if (rq_ci != rxq->rq_ci) {
1746 *rxq->rq_db = rte_cpu_to_be_32(rxq->rq_ci);
1748 #ifdef MLX5_PMD_SOFT_COUNTERS
1749 /* Increment packets counter. */
1750 rxq->stats.ipackets += i;
1756 * Dummy DPDK callback for TX.
1758 * This function is used to temporarily replace the real callback during
1759 * unsafe control operations on the queue, or in case of error.
1762 * Generic pointer to TX queue structure.
1764 * Packets to transmit.
1766 * Number of packets in array.
1769 * Number of packets successfully transmitted (<= pkts_n).
1772 removed_tx_burst(void *dpdk_txq __rte_unused,
1773 struct rte_mbuf **pkts __rte_unused,
1774 uint16_t pkts_n __rte_unused)
1781 * Dummy DPDK callback for RX.
1783 * This function is used to temporarily replace the real callback during
1784 * unsafe control operations on the queue, or in case of error.
1787 * Generic pointer to RX queue structure.
1789 * Array to store received packets.
1791 * Maximum number of packets in array.
1794 * Number of packets successfully received (<= pkts_n).
1797 removed_rx_burst(void *dpdk_txq __rte_unused,
1798 struct rte_mbuf **pkts __rte_unused,
1799 uint16_t pkts_n __rte_unused)
1806 * Vectorized Rx/Tx routines are not compiled in when required vector
1807 * instructions are not supported on a target architecture. The following null
1808 * stubs are needed for linkage when those are not included outside of this file
1809 * (e.g. mlx5_rxtx_vec_sse.c for x86).
1813 mlx5_rx_burst_vec(void *dpdk_txq __rte_unused,
1814 struct rte_mbuf **pkts __rte_unused,
1815 uint16_t pkts_n __rte_unused)
1821 mlx5_rxq_check_vec_support(struct mlx5_rxq_data *rxq __rte_unused)
1827 mlx5_check_vec_rx_support(struct rte_eth_dev *dev __rte_unused)
1833 * Free the mbufs from the linear array of pointers.
1836 * Pointer to array of packets to be free.
1838 * Number of packets to be freed.
1840 * Configured Tx offloads mask. It is fully defined at
1841 * compile time and may be used for optimization.
1843 static __rte_always_inline void
1844 mlx5_tx_free_mbuf(struct rte_mbuf **restrict pkts,
1845 unsigned int pkts_n,
1846 unsigned int olx __rte_unused)
1848 struct rte_mempool *pool = NULL;
1849 struct rte_mbuf **p_free = NULL;
1850 struct rte_mbuf *mbuf;
1851 unsigned int n_free = 0;
1854 * The implemented algorithm eliminates
1855 * copying pointers to temporary array
1856 * for rte_mempool_put_bulk() calls.
1863 * Decrement mbuf reference counter, detach
1864 * indirect and external buffers if needed.
1866 mbuf = rte_pktmbuf_prefree_seg(*pkts);
1867 if (likely(mbuf != NULL)) {
1868 assert(mbuf == *pkts);
1869 if (likely(n_free != 0)) {
1870 if (unlikely(pool != mbuf->pool))
1871 /* From different pool. */
1874 /* Start new scan array. */
1881 if (unlikely(pkts_n == 0)) {
1887 * This happens if mbuf is still referenced.
1888 * We can't put it back to the pool, skip.
1892 if (unlikely(n_free != 0))
1893 /* There is some array to free.*/
1895 if (unlikely(pkts_n == 0))
1896 /* Last mbuf, nothing to free. */
1902 * This loop is implemented to avoid multiple
1903 * inlining of rte_mempool_put_bulk().
1909 * Free the array of pre-freed mbufs
1910 * belonging to the same memory pool.
1912 rte_mempool_put_bulk(pool, (void *)p_free, n_free);
1913 if (unlikely(mbuf != NULL)) {
1914 /* There is the request to start new scan. */
1919 if (likely(pkts_n != 0))
1922 * This is the last mbuf to be freed.
1923 * Do one more loop iteration to complete.
1924 * This is rare case of the last unique mbuf.
1929 if (likely(pkts_n == 0))
1938 * Free the mbuf from the elts ring buffer till new tail.
1941 * Pointer to Tx queue structure.
1943 * Index in elts to free up to, becomes new elts tail.
1945 * Configured Tx offloads mask. It is fully defined at
1946 * compile time and may be used for optimization.
1948 static __rte_always_inline void
1949 mlx5_tx_free_elts(struct mlx5_txq_data *restrict txq,
1951 unsigned int olx __rte_unused)
1953 uint16_t n_elts = tail - txq->elts_tail;
1956 assert(n_elts <= txq->elts_s);
1958 * Implement a loop to support ring buffer wraparound
1959 * with single inlining of mlx5_tx_free_mbuf().
1964 part = txq->elts_s - (txq->elts_tail & txq->elts_m);
1965 part = RTE_MIN(part, n_elts);
1967 assert(part <= txq->elts_s);
1968 mlx5_tx_free_mbuf(&txq->elts[txq->elts_tail & txq->elts_m],
1970 txq->elts_tail += part;
1976 * Store the mbuf being sent into elts ring buffer.
1977 * On Tx completion these mbufs will be freed.
1980 * Pointer to Tx queue structure.
1982 * Pointer to array of packets to be stored.
1984 * Number of packets to be stored.
1986 * Configured Tx offloads mask. It is fully defined at
1987 * compile time and may be used for optimization.
1989 static __rte_always_inline void
1990 mlx5_tx_copy_elts(struct mlx5_txq_data *restrict txq,
1991 struct rte_mbuf **restrict pkts,
1992 unsigned int pkts_n,
1993 unsigned int olx __rte_unused)
1996 struct rte_mbuf **elts = (struct rte_mbuf **)txq->elts;
2000 part = txq->elts_s - (txq->elts_head & txq->elts_m);
2002 assert(part <= txq->elts_s);
2003 /* This code is a good candidate for vectorizing with SIMD. */
2004 rte_memcpy((void *)(elts + (txq->elts_head & txq->elts_m)),
2006 RTE_MIN(part, pkts_n) * sizeof(struct rte_mbuf *));
2007 txq->elts_head += pkts_n;
2008 if (unlikely(part < pkts_n))
2009 /* The copy is wrapping around the elts array. */
2010 rte_memcpy((void *)elts, (void *)(pkts + part),
2011 (pkts_n - part) * sizeof(struct rte_mbuf *));
2015 * Update completion queue consuming index via doorbell
2016 * and flush the completed data buffers.
2019 * Pointer to TX queue structure.
2020 * @param valid CQE pointer
2021 * if not NULL update txq->wqe_pi and flush the buffers
2023 * if not negative - flush the buffers till this index.
2025 * Configured Tx offloads mask. It is fully defined at
2026 * compile time and may be used for optimization.
2028 static __rte_always_inline void
2029 mlx5_tx_comp_flush(struct mlx5_txq_data *restrict txq,
2030 volatile struct mlx5_cqe *last_cqe,
2032 unsigned int olx __rte_unused)
2036 if (likely(last_cqe != NULL)) {
2037 txq->wqe_pi = rte_be_to_cpu_16(last_cqe->wqe_counter);
2038 tail = ((volatile struct mlx5_wqe_cseg *)
2039 (txq->wqes + (txq->wqe_pi & txq->wqe_m)))->misc;
2040 } else if (itail >= 0) {
2041 tail = (uint16_t)itail;
2045 rte_compiler_barrier();
2046 *txq->cq_db = rte_cpu_to_be_32(txq->cq_ci);
2047 if (likely(tail != txq->elts_tail)) {
2048 mlx5_tx_free_elts(txq, tail, olx);
2049 assert(tail == txq->elts_tail);
2054 * Manage TX completions. This routine checks the CQ for
2055 * arrived CQEs, deduces the last accomplished WQE in SQ,
2056 * updates SQ producing index and frees all completed mbufs.
2059 * Pointer to TX queue structure.
2061 * Configured Tx offloads mask. It is fully defined at
2062 * compile time and may be used for optimization.
2064 * NOTE: not inlined intentionally, it makes tx_burst
2065 * routine smaller, simple and faster - from experiments.
2068 mlx5_tx_handle_completion(struct mlx5_txq_data *restrict txq,
2069 unsigned int olx __rte_unused)
2071 unsigned int count = MLX5_TX_COMP_MAX_CQE;
2072 volatile struct mlx5_cqe *last_cqe = NULL;
2075 static_assert(MLX5_CQE_STATUS_HW_OWN < 0, "Must be negative value");
2076 static_assert(MLX5_CQE_STATUS_SW_OWN < 0, "Must be negative value");
2078 volatile struct mlx5_cqe *cqe;
2080 cqe = &txq->cqes[txq->cq_ci & txq->cqe_m];
2081 ret = check_cqe(cqe, txq->cqe_s, txq->cq_ci);
2082 if (unlikely(ret != MLX5_CQE_STATUS_SW_OWN)) {
2083 if (likely(ret != MLX5_CQE_STATUS_ERR)) {
2084 /* No new CQEs in completion queue. */
2085 assert(ret == MLX5_CQE_STATUS_HW_OWN);
2089 * Some error occurred, try to restart.
2090 * We have no barrier after WQE related Doorbell
2091 * written, make sure all writes are completed
2092 * here, before we might perform SQ reset.
2095 ret = mlx5_tx_error_cqe_handle
2096 (txq, (volatile struct mlx5_err_cqe *)cqe);
2098 * Flush buffers, update consuming index
2099 * if recovery succeeded. Otherwise
2100 * just try to recover later.
2105 /* Normal transmit completion. */
2113 * We have to restrict the amount of processed CQEs
2114 * in one tx_burst routine call. The CQ may be large
2115 * and many CQEs may be updated by the NIC in one
2116 * transaction. Buffers freeing is time consuming,
2117 * multiple iterations may introduce significant
2121 mlx5_tx_comp_flush(txq, last_cqe, ret, olx);
2125 * Check if the completion request flag should be set in the last WQE.
2126 * Both pushed mbufs and WQEs are monitored and the completion request
2127 * flag is set if any of thresholds is reached.
2130 * Pointer to TX queue structure.
2132 * Pointer to burst routine local context.
2134 * Routine is called from multi-segment sending loop,
2135 * do not correct the elts_head according to the pkts_copy.
2137 * Configured Tx offloads mask. It is fully defined at
2138 * compile time and may be used for optimization.
2140 static __rte_always_inline void
2141 mlx5_tx_request_completion(struct mlx5_txq_data *restrict txq,
2142 struct mlx5_txq_local *restrict loc,
2146 uint16_t head = txq->elts_head;
2149 part = (MLX5_TXOFF_CONFIG(INLINE) || multi) ?
2150 0 : loc->pkts_sent - loc->pkts_copy;
2152 if ((uint16_t)(head - txq->elts_comp) >= MLX5_TX_COMP_THRESH ||
2153 (MLX5_TXOFF_CONFIG(INLINE) &&
2154 (uint16_t)(txq->wqe_ci - txq->wqe_comp) >= txq->wqe_thres)) {
2155 volatile struct mlx5_wqe *last = loc->wqe_last;
2157 txq->elts_comp = head;
2158 if (MLX5_TXOFF_CONFIG(INLINE))
2159 txq->wqe_comp = txq->wqe_ci;
2160 /* Request unconditional completion on last WQE. */
2161 last->cseg.flags = RTE_BE32(MLX5_COMP_ALWAYS <<
2162 MLX5_COMP_MODE_OFFSET);
2163 /* Save elts_head in unused "immediate" field of WQE. */
2164 last->cseg.misc = head;
2166 * A CQE slot must always be available. Count the
2167 * issued CEQ "always" request instead of production
2168 * index due to here can be CQE with errors and
2169 * difference with ci may become inconsistent.
2171 assert(txq->cqe_s > ++txq->cq_pi);
2176 * DPDK callback to check the status of a tx descriptor.
2181 * The index of the descriptor in the ring.
2184 * The status of the tx descriptor.
2187 mlx5_tx_descriptor_status(void *tx_queue, uint16_t offset)
2189 struct mlx5_txq_data *restrict txq = tx_queue;
2192 mlx5_tx_handle_completion(txq, 0);
2193 used = txq->elts_head - txq->elts_tail;
2195 return RTE_ETH_TX_DESC_FULL;
2196 return RTE_ETH_TX_DESC_DONE;
2200 * Build the Control Segment with specified opcode:
2201 * - MLX5_OPCODE_SEND
2202 * - MLX5_OPCODE_ENHANCED_MPSW
2206 * Pointer to TX queue structure.
2208 * Pointer to burst routine local context.
2210 * Pointer to WQE to fill with built Control Segment.
2212 * Supposed length of WQE in segments.
2214 * SQ WQE opcode to put into Control Segment.
2216 * Configured Tx offloads mask. It is fully defined at
2217 * compile time and may be used for optimization.
2219 static __rte_always_inline void
2220 mlx5_tx_cseg_init(struct mlx5_txq_data *restrict txq,
2221 struct mlx5_txq_local *restrict loc __rte_unused,
2222 struct mlx5_wqe *restrict wqe,
2224 unsigned int opcode,
2225 unsigned int olx __rte_unused)
2227 struct mlx5_wqe_cseg *restrict cs = &wqe->cseg;
2229 cs->opcode = rte_cpu_to_be_32((txq->wqe_ci << 8) | opcode);
2230 cs->sq_ds = rte_cpu_to_be_32(txq->qp_num_8s | ds);
2231 cs->flags = RTE_BE32(MLX5_COMP_ONLY_FIRST_ERR <<
2232 MLX5_COMP_MODE_OFFSET);
2233 cs->misc = RTE_BE32(0);
2237 * Build the Ethernet Segment without inlined data.
2238 * Supports Software Parser, Checksums and VLAN
2239 * insertion Tx offload features.
2242 * Pointer to TX queue structure.
2244 * Pointer to burst routine local context.
2246 * Pointer to WQE to fill with built Ethernet Segment.
2248 * Configured Tx offloads mask. It is fully defined at
2249 * compile time and may be used for optimization.
2251 static __rte_always_inline void
2252 mlx5_tx_eseg_none(struct mlx5_txq_data *restrict txq __rte_unused,
2253 struct mlx5_txq_local *restrict loc,
2254 struct mlx5_wqe *restrict wqe,
2257 struct mlx5_wqe_eseg *restrict es = &wqe->eseg;
2261 * Calculate and set check sum flags first, dword field
2262 * in segment may be shared with Software Parser flags.
2264 csum = MLX5_TXOFF_CONFIG(CSUM) ? txq_ol_cksum_to_cs(loc->mbuf) : 0;
2265 es->flags = rte_cpu_to_le_32(csum);
2267 * Calculate and set Software Parser offsets and flags.
2268 * These flags a set for custom UDP and IP tunnel packets.
2270 es->swp_offs = txq_mbuf_to_swp(loc, &es->swp_flags, olx);
2271 /* Fill metadata field if needed. */
2272 es->metadata = MLX5_TXOFF_CONFIG(METADATA) ?
2273 loc->mbuf->ol_flags & PKT_TX_METADATA ?
2274 loc->mbuf->tx_metadata : 0 : 0;
2275 /* Engage VLAN tag insertion feature if requested. */
2276 if (MLX5_TXOFF_CONFIG(VLAN) &&
2277 loc->mbuf->ol_flags & PKT_TX_VLAN_PKT) {
2279 * We should get here only if device support
2280 * this feature correctly.
2282 assert(txq->vlan_en);
2283 es->inline_hdr = rte_cpu_to_be_32(MLX5_ETH_WQE_VLAN_INSERT |
2284 loc->mbuf->vlan_tci);
2286 es->inline_hdr = RTE_BE32(0);
2291 * Build the Ethernet Segment with minimal inlined data
2292 * of MLX5_ESEG_MIN_INLINE_SIZE bytes length. This is
2293 * used to fill the gap in single WQEBB WQEs.
2294 * Supports Software Parser, Checksums and VLAN
2295 * insertion Tx offload features.
2298 * Pointer to TX queue structure.
2300 * Pointer to burst routine local context.
2302 * Pointer to WQE to fill with built Ethernet Segment.
2304 * Length of VLAN tag insertion if any.
2306 * Configured Tx offloads mask. It is fully defined at
2307 * compile time and may be used for optimization.
2309 static __rte_always_inline void
2310 mlx5_tx_eseg_dmin(struct mlx5_txq_data *restrict txq __rte_unused,
2311 struct mlx5_txq_local *restrict loc,
2312 struct mlx5_wqe *restrict wqe,
2316 struct mlx5_wqe_eseg *restrict es = &wqe->eseg;
2318 uint8_t *psrc, *pdst;
2321 * Calculate and set check sum flags first, dword field
2322 * in segment may be shared with Software Parser flags.
2324 csum = MLX5_TXOFF_CONFIG(CSUM) ? txq_ol_cksum_to_cs(loc->mbuf) : 0;
2325 es->flags = rte_cpu_to_le_32(csum);
2327 * Calculate and set Software Parser offsets and flags.
2328 * These flags a set for custom UDP and IP tunnel packets.
2330 es->swp_offs = txq_mbuf_to_swp(loc, &es->swp_flags, olx);
2331 /* Fill metadata field if needed. */
2332 es->metadata = MLX5_TXOFF_CONFIG(METADATA) ?
2333 loc->mbuf->ol_flags & PKT_TX_METADATA ?
2334 loc->mbuf->tx_metadata : 0 : 0;
2335 static_assert(MLX5_ESEG_MIN_INLINE_SIZE ==
2337 sizeof(rte_v128u32_t)),
2338 "invalid Ethernet Segment data size");
2339 static_assert(MLX5_ESEG_MIN_INLINE_SIZE ==
2341 sizeof(struct rte_vlan_hdr) +
2342 2 * RTE_ETHER_ADDR_LEN),
2343 "invalid Ethernet Segment data size");
2344 psrc = rte_pktmbuf_mtod(loc->mbuf, uint8_t *);
2345 es->inline_hdr_sz = RTE_BE16(MLX5_ESEG_MIN_INLINE_SIZE);
2346 es->inline_data = *(unaligned_uint16_t *)psrc;
2347 psrc += sizeof(uint16_t);
2348 pdst = (uint8_t *)(es + 1);
2349 if (MLX5_TXOFF_CONFIG(VLAN) && vlan) {
2350 /* Implement VLAN tag insertion as part inline data. */
2351 memcpy(pdst, psrc, 2 * RTE_ETHER_ADDR_LEN - sizeof(uint16_t));
2352 pdst += 2 * RTE_ETHER_ADDR_LEN - sizeof(uint16_t);
2353 psrc += 2 * RTE_ETHER_ADDR_LEN - sizeof(uint16_t);
2354 /* Insert VLAN ethertype + VLAN tag. */
2355 *(unaligned_uint32_t *)pdst = rte_cpu_to_be_32
2356 ((RTE_ETHER_TYPE_VLAN << 16) |
2357 loc->mbuf->vlan_tci);
2358 pdst += sizeof(struct rte_vlan_hdr);
2359 /* Copy the rest two bytes from packet data. */
2360 assert(pdst == RTE_PTR_ALIGN(pdst, sizeof(uint16_t)));
2361 *(uint16_t *)pdst = *(unaligned_uint16_t *)psrc;
2363 /* Fill the gap in the title WQEBB with inline data. */
2364 rte_mov16(pdst, psrc);
2369 * Build the Ethernet Segment with entire packet
2370 * data inlining. Checks the boundary of WQEBB and
2371 * ring buffer wrapping, supports Software Parser,
2372 * Checksums and VLAN insertion Tx offload features.
2375 * Pointer to TX queue structure.
2377 * Pointer to burst routine local context.
2379 * Pointer to WQE to fill with built Ethernet Segment.
2381 * Length of VLAN tag insertion if any.
2383 * Length of data to inline (VLAN included, if any).
2385 * TSO flag, set mss field from the packet.
2387 * Configured Tx offloads mask. It is fully defined at
2388 * compile time and may be used for optimization.
2391 * Pointer to the next Data Segment (aligned and wrapped around).
2393 static __rte_always_inline struct mlx5_wqe_dseg *
2394 mlx5_tx_eseg_data(struct mlx5_txq_data *restrict txq,
2395 struct mlx5_txq_local *restrict loc,
2396 struct mlx5_wqe *restrict wqe,
2402 struct mlx5_wqe_eseg *restrict es = &wqe->eseg;
2404 uint8_t *psrc, *pdst;
2408 * Calculate and set check sum flags first, dword field
2409 * in segment may be shared with Software Parser flags.
2411 csum = MLX5_TXOFF_CONFIG(CSUM) ? txq_ol_cksum_to_cs(loc->mbuf) : 0;
2414 csum |= loc->mbuf->tso_segsz;
2415 es->flags = rte_cpu_to_be_32(csum);
2417 es->flags = rte_cpu_to_le_32(csum);
2420 * Calculate and set Software Parser offsets and flags.
2421 * These flags a set for custom UDP and IP tunnel packets.
2423 es->swp_offs = txq_mbuf_to_swp(loc, &es->swp_flags, olx);
2424 /* Fill metadata field if needed. */
2425 es->metadata = MLX5_TXOFF_CONFIG(METADATA) ?
2426 loc->mbuf->ol_flags & PKT_TX_METADATA ?
2427 loc->mbuf->tx_metadata : 0 : 0;
2428 static_assert(MLX5_ESEG_MIN_INLINE_SIZE ==
2430 sizeof(rte_v128u32_t)),
2431 "invalid Ethernet Segment data size");
2432 static_assert(MLX5_ESEG_MIN_INLINE_SIZE ==
2434 sizeof(struct rte_vlan_hdr) +
2435 2 * RTE_ETHER_ADDR_LEN),
2436 "invalid Ethernet Segment data size");
2437 psrc = rte_pktmbuf_mtod(loc->mbuf, uint8_t *);
2438 es->inline_hdr_sz = rte_cpu_to_be_16(inlen);
2439 es->inline_data = *(unaligned_uint16_t *)psrc;
2440 psrc += sizeof(uint16_t);
2441 pdst = (uint8_t *)(es + 1);
2442 if (MLX5_TXOFF_CONFIG(VLAN) && vlan) {
2443 /* Implement VLAN tag insertion as part inline data. */
2444 memcpy(pdst, psrc, 2 * RTE_ETHER_ADDR_LEN - sizeof(uint16_t));
2445 pdst += 2 * RTE_ETHER_ADDR_LEN - sizeof(uint16_t);
2446 psrc += 2 * RTE_ETHER_ADDR_LEN - sizeof(uint16_t);
2447 /* Insert VLAN ethertype + VLAN tag. */
2448 *(unaligned_uint32_t *)pdst = rte_cpu_to_be_32
2449 ((RTE_ETHER_TYPE_VLAN << 16) |
2450 loc->mbuf->vlan_tci);
2451 pdst += sizeof(struct rte_vlan_hdr);
2452 /* Copy the rest two bytes from packet data. */
2453 assert(pdst == RTE_PTR_ALIGN(pdst, sizeof(uint16_t)));
2454 *(uint16_t *)pdst = *(unaligned_uint16_t *)psrc;
2455 psrc += sizeof(uint16_t);
2457 /* Fill the gap in the title WQEBB with inline data. */
2458 rte_mov16(pdst, psrc);
2459 psrc += sizeof(rte_v128u32_t);
2461 pdst = (uint8_t *)(es + 2);
2462 assert(inlen >= MLX5_ESEG_MIN_INLINE_SIZE);
2463 assert(pdst < (uint8_t *)txq->wqes_end);
2464 inlen -= MLX5_ESEG_MIN_INLINE_SIZE;
2466 assert(pdst == RTE_PTR_ALIGN(pdst, MLX5_WSEG_SIZE));
2467 return (struct mlx5_wqe_dseg *)pdst;
2470 * The WQEBB space availability is checked by caller.
2471 * Here we should be aware of WQE ring buffer wraparound only.
2473 part = (uint8_t *)txq->wqes_end - pdst;
2474 part = RTE_MIN(part, inlen);
2476 rte_memcpy(pdst, psrc, part);
2478 if (likely(!inlen)) {
2480 * If return value is not used by the caller
2481 * the code below will be optimized out.
2484 pdst = RTE_PTR_ALIGN(pdst, MLX5_WSEG_SIZE);
2485 if (unlikely(pdst >= (uint8_t *)txq->wqes_end))
2486 pdst = (uint8_t *)txq->wqes;
2487 return (struct mlx5_wqe_dseg *)pdst;
2489 pdst = (uint8_t *)txq->wqes;
2496 * Copy data from chain of mbuf to the specified linear buffer.
2497 * Checksums and VLAN insertion Tx offload features. If data
2498 * from some mbuf copied completely this mbuf is freed. Local
2499 * structure is used to keep the byte stream state.
2502 * Pointer to the destination linear buffer.
2504 * Pointer to burst routine local context.
2506 * Length of data to be copied.
2508 * Configured Tx offloads mask. It is fully defined at
2509 * compile time and may be used for optimization.
2511 static __rte_always_inline void
2512 mlx5_tx_mseg_memcpy(uint8_t *pdst,
2513 struct mlx5_txq_local *restrict loc,
2515 unsigned int olx __rte_unused)
2517 struct rte_mbuf *mbuf;
2518 unsigned int part, dlen;
2523 /* Allow zero length packets, must check first. */
2524 dlen = rte_pktmbuf_data_len(loc->mbuf);
2525 if (dlen <= loc->mbuf_off) {
2526 /* Exhausted packet, just free. */
2528 loc->mbuf = mbuf->next;
2529 rte_pktmbuf_free_seg(mbuf);
2531 assert(loc->mbuf_nseg > 1);
2536 dlen -= loc->mbuf_off;
2537 psrc = rte_pktmbuf_mtod_offset(loc->mbuf, uint8_t *,
2539 part = RTE_MIN(len, dlen);
2540 rte_memcpy(pdst, psrc, part);
2541 loc->mbuf_off += part;
2544 if (loc->mbuf_off >= rte_pktmbuf_data_len(loc->mbuf)) {
2546 /* Exhausted packet, just free. */
2548 loc->mbuf = mbuf->next;
2549 rte_pktmbuf_free_seg(mbuf);
2551 assert(loc->mbuf_nseg >= 1);
2561 * Build the Ethernet Segment with inlined data from
2562 * multi-segment packet. Checks the boundary of WQEBB
2563 * and ring buffer wrapping, supports Software Parser,
2564 * Checksums and VLAN insertion Tx offload features.
2567 * Pointer to TX queue structure.
2569 * Pointer to burst routine local context.
2571 * Pointer to WQE to fill with built Ethernet Segment.
2573 * Length of VLAN tag insertion if any.
2575 * Length of data to inline (VLAN included, if any).
2577 * TSO flag, set mss field from the packet.
2579 * Configured Tx offloads mask. It is fully defined at
2580 * compile time and may be used for optimization.
2583 * Pointer to the next Data Segment (aligned and
2584 * possible NOT wrapped around - caller should do
2585 * wrapping check on its own).
2587 static __rte_always_inline struct mlx5_wqe_dseg *
2588 mlx5_tx_eseg_mdat(struct mlx5_txq_data *restrict txq,
2589 struct mlx5_txq_local *restrict loc,
2590 struct mlx5_wqe *restrict wqe,
2596 struct mlx5_wqe_eseg *restrict es = &wqe->eseg;
2602 * Calculate and set check sum flags first, uint32_t field
2603 * in segment may be shared with Software Parser flags.
2605 csum = MLX5_TXOFF_CONFIG(CSUM) ? txq_ol_cksum_to_cs(loc->mbuf) : 0;
2608 csum |= loc->mbuf->tso_segsz;
2609 es->flags = rte_cpu_to_be_32(csum);
2611 es->flags = rte_cpu_to_le_32(csum);
2614 * Calculate and set Software Parser offsets and flags.
2615 * These flags a set for custom UDP and IP tunnel packets.
2617 es->swp_offs = txq_mbuf_to_swp(loc, &es->swp_flags, olx);
2618 /* Fill metadata field if needed. */
2619 es->metadata = MLX5_TXOFF_CONFIG(METADATA) ?
2620 loc->mbuf->ol_flags & PKT_TX_METADATA ?
2621 loc->mbuf->tx_metadata : 0 : 0;
2622 static_assert(MLX5_ESEG_MIN_INLINE_SIZE ==
2624 sizeof(rte_v128u32_t)),
2625 "invalid Ethernet Segment data size");
2626 static_assert(MLX5_ESEG_MIN_INLINE_SIZE ==
2628 sizeof(struct rte_vlan_hdr) +
2629 2 * RTE_ETHER_ADDR_LEN),
2630 "invalid Ethernet Segment data size");
2631 assert(inlen >= MLX5_ESEG_MIN_INLINE_SIZE);
2632 es->inline_hdr_sz = rte_cpu_to_be_16(inlen);
2633 pdst = (uint8_t *)&es->inline_data;
2634 if (MLX5_TXOFF_CONFIG(VLAN) && vlan) {
2635 /* Implement VLAN tag insertion as part inline data. */
2636 mlx5_tx_mseg_memcpy(pdst, loc, 2 * RTE_ETHER_ADDR_LEN, olx);
2637 pdst += 2 * RTE_ETHER_ADDR_LEN;
2638 *(unaligned_uint32_t *)pdst = rte_cpu_to_be_32
2639 ((RTE_ETHER_TYPE_VLAN << 16) |
2640 loc->mbuf->vlan_tci);
2641 pdst += sizeof(struct rte_vlan_hdr);
2642 inlen -= 2 * RTE_ETHER_ADDR_LEN + sizeof(struct rte_vlan_hdr);
2644 assert(pdst < (uint8_t *)txq->wqes_end);
2646 * The WQEBB space availability is checked by caller.
2647 * Here we should be aware of WQE ring buffer wraparound only.
2649 part = (uint8_t *)txq->wqes_end - pdst;
2650 part = RTE_MIN(part, inlen);
2653 mlx5_tx_mseg_memcpy(pdst, loc, part, olx);
2655 if (likely(!inlen)) {
2657 pdst = RTE_PTR_ALIGN(pdst, MLX5_WSEG_SIZE);
2658 return (struct mlx5_wqe_dseg *)pdst;
2660 pdst = (uint8_t *)txq->wqes;
2666 * Build the Data Segment of pointer type.
2669 * Pointer to TX queue structure.
2671 * Pointer to burst routine local context.
2673 * Pointer to WQE to fill with built Data Segment.
2675 * Data buffer to point.
2677 * Data buffer length.
2679 * Configured Tx offloads mask. It is fully defined at
2680 * compile time and may be used for optimization.
2682 static __rte_always_inline void
2683 mlx5_tx_dseg_ptr(struct mlx5_txq_data *restrict txq,
2684 struct mlx5_txq_local *restrict loc,
2685 struct mlx5_wqe_dseg *restrict dseg,
2688 unsigned int olx __rte_unused)
2692 dseg->bcount = rte_cpu_to_be_32(len);
2693 dseg->lkey = mlx5_tx_mb2mr(txq, loc->mbuf);
2694 dseg->pbuf = rte_cpu_to_be_64((uintptr_t)buf);
2698 * Build the Data Segment of pointer type or inline
2699 * if data length is less than buffer in minimal
2700 * Data Segment size.
2703 * Pointer to TX queue structure.
2705 * Pointer to burst routine local context.
2707 * Pointer to WQE to fill with built Data Segment.
2709 * Data buffer to point.
2711 * Data buffer length.
2713 * Configured Tx offloads mask. It is fully defined at
2714 * compile time and may be used for optimization.
2716 static __rte_always_inline void
2717 mlx5_tx_dseg_iptr(struct mlx5_txq_data *restrict txq,
2718 struct mlx5_txq_local *restrict loc,
2719 struct mlx5_wqe_dseg *restrict dseg,
2722 unsigned int olx __rte_unused)
2728 if (len > MLX5_DSEG_MIN_INLINE_SIZE) {
2729 dseg->bcount = rte_cpu_to_be_32(len);
2730 dseg->lkey = mlx5_tx_mb2mr(txq, loc->mbuf);
2731 dseg->pbuf = rte_cpu_to_be_64((uintptr_t)buf);
2735 dseg->bcount = rte_cpu_to_be_32(len | MLX5_ETH_WQE_DATA_INLINE);
2736 /* Unrolled implementation of generic rte_memcpy. */
2737 dst = (uintptr_t)&dseg->inline_data[0];
2738 src = (uintptr_t)buf;
2739 #ifdef RTE_ARCH_STRICT_ALIGN
2740 memcpy(dst, src, len);
2743 *(uint64_t *)dst = *(uint64_t *)src;
2744 dst += sizeof(uint64_t);
2745 src += sizeof(uint64_t);
2748 *(uint32_t *)dst = *(uint32_t *)src;
2749 dst += sizeof(uint32_t);
2750 src += sizeof(uint32_t);
2753 *(uint16_t *)dst = *(uint16_t *)src;
2754 dst += sizeof(uint16_t);
2755 src += sizeof(uint16_t);
2758 *(uint8_t *)dst = *(uint8_t *)src;
2763 * Build the Data Segment of inlined data from single
2764 * segment packet, no VLAN insertion.
2767 * Pointer to TX queue structure.
2769 * Pointer to burst routine local context.
2771 * Pointer to WQE to fill with built Data Segment.
2773 * Data buffer to point.
2775 * Data buffer length.
2777 * Configured Tx offloads mask. It is fully defined at
2778 * compile time and may be used for optimization.
2781 * Pointer to the next Data Segment after inlined data.
2782 * Ring buffer wraparound check is needed. We do not
2783 * do it here because it may not be needed for the
2784 * last packet in the eMPW session.
2786 static __rte_always_inline struct mlx5_wqe_dseg *
2787 mlx5_tx_dseg_empw(struct mlx5_txq_data *restrict txq,
2788 struct mlx5_txq_local *restrict loc __rte_unused,
2789 struct mlx5_wqe_dseg *restrict dseg,
2792 unsigned int olx __rte_unused)
2797 dseg->bcount = rte_cpu_to_be_32(len | MLX5_ETH_WQE_DATA_INLINE);
2798 pdst = &dseg->inline_data[0];
2800 * The WQEBB space availability is checked by caller.
2801 * Here we should be aware of WQE ring buffer wraparound only.
2803 part = (uint8_t *)txq->wqes_end - pdst;
2804 part = RTE_MIN(part, len);
2806 rte_memcpy(pdst, buf, part);
2810 pdst = RTE_PTR_ALIGN(pdst, MLX5_WSEG_SIZE);
2811 /* Note: no final wraparound check here. */
2812 return (struct mlx5_wqe_dseg *)pdst;
2814 pdst = (uint8_t *)txq->wqes;
2821 * Build the Data Segment of inlined data from single
2822 * segment packet with VLAN insertion.
2825 * Pointer to TX queue structure.
2827 * Pointer to burst routine local context.
2829 * Pointer to the dseg fill with built Data Segment.
2831 * Data buffer to point.
2833 * Data buffer length.
2835 * Configured Tx offloads mask. It is fully defined at
2836 * compile time and may be used for optimization.
2839 * Pointer to the next Data Segment after inlined data.
2840 * Ring buffer wraparound check is needed.
2842 static __rte_always_inline struct mlx5_wqe_dseg *
2843 mlx5_tx_dseg_vlan(struct mlx5_txq_data *restrict txq,
2844 struct mlx5_txq_local *restrict loc __rte_unused,
2845 struct mlx5_wqe_dseg *restrict dseg,
2848 unsigned int olx __rte_unused)
2854 assert(len > MLX5_ESEG_MIN_INLINE_SIZE);
2855 static_assert(MLX5_DSEG_MIN_INLINE_SIZE ==
2856 (2 * RTE_ETHER_ADDR_LEN),
2857 "invalid Data Segment data size");
2858 dseg->bcount = rte_cpu_to_be_32((len + sizeof(struct rte_vlan_hdr)) |
2859 MLX5_ETH_WQE_DATA_INLINE);
2860 pdst = &dseg->inline_data[0];
2861 memcpy(pdst, buf, MLX5_DSEG_MIN_INLINE_SIZE);
2862 buf += MLX5_DSEG_MIN_INLINE_SIZE;
2863 pdst += MLX5_DSEG_MIN_INLINE_SIZE;
2864 len -= MLX5_DSEG_MIN_INLINE_SIZE;
2865 /* Insert VLAN ethertype + VLAN tag. Pointer is aligned. */
2866 assert(pdst == RTE_PTR_ALIGN(pdst, MLX5_WSEG_SIZE));
2867 if (unlikely(pdst >= (uint8_t *)txq->wqes_end))
2868 pdst = (uint8_t *)txq->wqes;
2869 *(uint32_t *)pdst = rte_cpu_to_be_32((RTE_ETHER_TYPE_VLAN << 16) |
2870 loc->mbuf->vlan_tci);
2871 pdst += sizeof(struct rte_vlan_hdr);
2873 * The WQEBB space availability is checked by caller.
2874 * Here we should be aware of WQE ring buffer wraparound only.
2876 part = (uint8_t *)txq->wqes_end - pdst;
2877 part = RTE_MIN(part, len);
2879 rte_memcpy(pdst, buf, part);
2883 pdst = RTE_PTR_ALIGN(pdst, MLX5_WSEG_SIZE);
2884 /* Note: no final wraparound check here. */
2885 return (struct mlx5_wqe_dseg *)pdst;
2887 pdst = (uint8_t *)txq->wqes;
2894 * Build the Ethernet Segment with optionally inlined data with
2895 * VLAN insertion and following Data Segments (if any) from
2896 * multi-segment packet. Used by ordinary send and TSO.
2899 * Pointer to TX queue structure.
2901 * Pointer to burst routine local context.
2903 * Pointer to WQE to fill with built Ethernet/Data Segments.
2905 * Length of VLAN header to insert, 0 means no VLAN insertion.
2907 * Data length to inline. For TSO this parameter specifies
2908 * exact value, for ordinary send routine can be aligned by
2909 * caller to provide better WQE space saving and data buffer
2910 * start address alignment. This length includes VLAN header
2913 * Zero means ordinary send, inlined data can be extended,
2914 * otherwise this is TSO, inlined data length is fixed.
2916 * Configured Tx offloads mask. It is fully defined at
2917 * compile time and may be used for optimization.
2920 * Actual size of built WQE in segments.
2922 static __rte_always_inline unsigned int
2923 mlx5_tx_mseg_build(struct mlx5_txq_data *restrict txq,
2924 struct mlx5_txq_local *restrict loc,
2925 struct mlx5_wqe *restrict wqe,
2929 unsigned int olx __rte_unused)
2931 struct mlx5_wqe_dseg *restrict dseg;
2934 assert((rte_pktmbuf_pkt_len(loc->mbuf) + vlan) >= inlen);
2935 loc->mbuf_nseg = NB_SEGS(loc->mbuf);
2938 dseg = mlx5_tx_eseg_mdat(txq, loc, wqe, vlan, inlen, tso, olx);
2939 if (!loc->mbuf_nseg)
2942 * There are still some mbuf remaining, not inlined.
2943 * The first mbuf may be partially inlined and we
2944 * must process the possible non-zero data offset.
2946 if (loc->mbuf_off) {
2951 * Exhausted packets must be dropped before.
2952 * Non-zero offset means there are some data
2953 * remained in the packet.
2955 assert(loc->mbuf_off < rte_pktmbuf_data_len(loc->mbuf));
2956 assert(rte_pktmbuf_data_len(loc->mbuf));
2957 dptr = rte_pktmbuf_mtod_offset(loc->mbuf, uint8_t *,
2959 dlen = rte_pktmbuf_data_len(loc->mbuf) - loc->mbuf_off;
2961 * Build the pointer/minimal data Data Segment.
2962 * Do ring buffer wrapping check in advance.
2964 if ((uintptr_t)dseg >= (uintptr_t)txq->wqes_end)
2965 dseg = (struct mlx5_wqe_dseg *)txq->wqes;
2966 mlx5_tx_dseg_iptr(txq, loc, dseg, dptr, dlen, olx);
2967 /* Store the mbuf to be freed on completion. */
2968 assert(loc->elts_free);
2969 txq->elts[txq->elts_head++ & txq->elts_m] = loc->mbuf;
2972 if (--loc->mbuf_nseg == 0)
2974 loc->mbuf = loc->mbuf->next;
2978 if (unlikely(!rte_pktmbuf_data_len(loc->mbuf))) {
2979 struct rte_mbuf *mbuf;
2981 /* Zero length segment found, just skip. */
2983 loc->mbuf = loc->mbuf->next;
2984 rte_pktmbuf_free_seg(mbuf);
2985 if (--loc->mbuf_nseg == 0)
2988 if ((uintptr_t)dseg >= (uintptr_t)txq->wqes_end)
2989 dseg = (struct mlx5_wqe_dseg *)txq->wqes;
2992 rte_pktmbuf_mtod(loc->mbuf, uint8_t *),
2993 rte_pktmbuf_data_len(loc->mbuf), olx);
2994 assert(loc->elts_free);
2995 txq->elts[txq->elts_head++ & txq->elts_m] = loc->mbuf;
2998 if (--loc->mbuf_nseg == 0)
3000 loc->mbuf = loc->mbuf->next;
3005 /* Calculate actual segments used from the dseg pointer. */
3006 if ((uintptr_t)wqe < (uintptr_t)dseg)
3007 ds = ((uintptr_t)dseg - (uintptr_t)wqe) / MLX5_WSEG_SIZE;
3009 ds = (((uintptr_t)dseg - (uintptr_t)wqe) +
3010 txq->wqe_s * MLX5_WQE_SIZE) / MLX5_WSEG_SIZE;
3015 * Tx one packet function for multi-segment TSO. Supports all
3016 * types of Tx offloads, uses MLX5_OPCODE_TSO to build WQEs,
3017 * sends one packet per WQE.
3019 * This routine is responsible for storing processed mbuf
3020 * into elts ring buffer and update elts_head.
3023 * Pointer to TX queue structure.
3025 * Pointer to burst routine local context.
3027 * Configured Tx offloads mask. It is fully defined at
3028 * compile time and may be used for optimization.
3031 * MLX5_TXCMP_CODE_EXIT - sending is done or impossible.
3032 * MLX5_TXCMP_CODE_ERROR - some unrecoverable error occurred.
3033 * Local context variables partially updated.
3035 static __rte_always_inline enum mlx5_txcmp_code
3036 mlx5_tx_packet_multi_tso(struct mlx5_txq_data *restrict txq,
3037 struct mlx5_txq_local *restrict loc,
3040 struct mlx5_wqe *restrict wqe;
3041 unsigned int ds, dlen, inlen, ntcp, vlan = 0;
3044 * Calculate data length to be inlined to estimate
3045 * the required space in WQE ring buffer.
3047 dlen = rte_pktmbuf_pkt_len(loc->mbuf);
3048 if (MLX5_TXOFF_CONFIG(VLAN) && loc->mbuf->ol_flags & PKT_TX_VLAN_PKT)
3049 vlan = sizeof(struct rte_vlan_hdr);
3050 inlen = loc->mbuf->l2_len + vlan +
3051 loc->mbuf->l3_len + loc->mbuf->l4_len;
3052 if (unlikely((!inlen || !loc->mbuf->tso_segsz)))
3053 return MLX5_TXCMP_CODE_ERROR;
3054 if (loc->mbuf->ol_flags & PKT_TX_TUNNEL_MASK)
3055 inlen += loc->mbuf->outer_l2_len + loc->mbuf->outer_l3_len;
3056 /* Packet must contain all TSO headers. */
3057 if (unlikely(inlen > MLX5_MAX_TSO_HEADER ||
3058 inlen <= MLX5_ESEG_MIN_INLINE_SIZE ||
3059 inlen > (dlen + vlan)))
3060 return MLX5_TXCMP_CODE_ERROR;
3061 assert(inlen >= txq->inlen_mode);
3063 * Check whether there are enough free WQEBBs:
3065 * - Ethernet Segment
3066 * - First Segment of inlined Ethernet data
3067 * - ... data continued ...
3068 * - Data Segments of pointer/min inline type
3070 ds = NB_SEGS(loc->mbuf) + 2 + (inlen -
3071 MLX5_ESEG_MIN_INLINE_SIZE +
3073 MLX5_WSEG_SIZE - 1) / MLX5_WSEG_SIZE;
3074 if (unlikely(loc->wqe_free < ((ds + 3) / 4)))
3075 return MLX5_TXCMP_CODE_EXIT;
3076 /* Check for maximal WQE size. */
3077 if (unlikely((MLX5_WQE_SIZE_MAX / MLX5_WSEG_SIZE) < ((ds + 3) / 4)))
3078 return MLX5_TXCMP_CODE_ERROR;
3079 #ifdef MLX5_PMD_SOFT_COUNTERS
3080 /* Update sent data bytes/packets counters. */
3081 ntcp = (dlen - (inlen - vlan) + loc->mbuf->tso_segsz - 1) /
3082 loc->mbuf->tso_segsz;
3084 * One will be added for mbuf itself
3085 * at the end of the mlx5_tx_burst from
3086 * loc->pkts_sent field.
3089 txq->stats.opackets += ntcp;
3090 txq->stats.obytes += dlen + vlan + ntcp * inlen;
3092 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
3093 loc->wqe_last = wqe;
3094 mlx5_tx_cseg_init(txq, loc, wqe, 0, MLX5_OPCODE_TSO, olx);
3095 ds = mlx5_tx_mseg_build(txq, loc, wqe, vlan, inlen, 1, olx);
3096 wqe->cseg.sq_ds = rte_cpu_to_be_32(txq->qp_num_8s | ds);
3097 txq->wqe_ci += (ds + 3) / 4;
3098 loc->wqe_free -= (ds + 3) / 4;
3099 /* Request CQE generation if limits are reached. */
3100 mlx5_tx_request_completion(txq, loc, true, olx);
3101 return MLX5_TXCMP_CODE_MULTI;
3105 * Tx one packet function for multi-segment SEND. Supports all
3106 * types of Tx offloads, uses MLX5_OPCODE_SEND to build WQEs,
3107 * sends one packet per WQE, without any data inlining in
3110 * This routine is responsible for storing processed mbuf
3111 * into elts ring buffer and update elts_head.
3114 * Pointer to TX queue structure.
3116 * Pointer to burst routine local context.
3118 * Configured Tx offloads mask. It is fully defined at
3119 * compile time and may be used for optimization.
3122 * MLX5_TXCMP_CODE_EXIT - sending is done or impossible.
3123 * MLX5_TXCMP_CODE_ERROR - some unrecoverable error occurred.
3124 * Local context variables partially updated.
3126 static __rte_always_inline enum mlx5_txcmp_code
3127 mlx5_tx_packet_multi_send(struct mlx5_txq_data *restrict txq,
3128 struct mlx5_txq_local *restrict loc,
3131 struct mlx5_wqe_dseg *restrict dseg;
3132 struct mlx5_wqe *restrict wqe;
3133 unsigned int ds, nseg;
3135 assert(NB_SEGS(loc->mbuf) > 1);
3137 * No inline at all, it means the CPU cycles saving
3138 * is prioritized at configuration, we should not
3139 * copy any packet data to WQE.
3141 nseg = NB_SEGS(loc->mbuf);
3143 if (unlikely(loc->wqe_free < ((ds + 3) / 4)))
3144 return MLX5_TXCMP_CODE_EXIT;
3145 /* Check for maximal WQE size. */
3146 if (unlikely((MLX5_WQE_SIZE_MAX / MLX5_WSEG_SIZE) < ((ds + 3) / 4)))
3147 return MLX5_TXCMP_CODE_ERROR;
3149 * Some Tx offloads may cause an error if
3150 * packet is not long enough, check against
3151 * assumed minimal length.
3153 if (rte_pktmbuf_pkt_len(loc->mbuf) <= MLX5_ESEG_MIN_INLINE_SIZE)
3154 return MLX5_TXCMP_CODE_ERROR;
3155 #ifdef MLX5_PMD_SOFT_COUNTERS
3156 /* Update sent data bytes counter. */
3157 txq->stats.obytes += rte_pktmbuf_pkt_len(loc->mbuf);
3158 if (MLX5_TXOFF_CONFIG(VLAN) &&
3159 loc->mbuf->ol_flags & PKT_TX_VLAN_PKT)
3160 txq->stats.obytes += sizeof(struct rte_vlan_hdr);
3163 * SEND WQE, one WQEBB:
3164 * - Control Segment, SEND opcode
3165 * - Ethernet Segment, optional VLAN, no inline
3166 * - Data Segments, pointer only type
3168 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
3169 loc->wqe_last = wqe;
3170 mlx5_tx_cseg_init(txq, loc, wqe, ds, MLX5_OPCODE_SEND, olx);
3171 mlx5_tx_eseg_none(txq, loc, wqe, olx);
3172 dseg = &wqe->dseg[0];
3174 if (unlikely(!rte_pktmbuf_data_len(loc->mbuf))) {
3175 struct rte_mbuf *mbuf;
3178 * Zero length segment found, have to
3179 * correct total size of WQE in segments.
3180 * It is supposed to be rare occasion, so
3181 * in normal case (no zero length segments)
3182 * we avoid extra writing to the Control
3186 wqe->cseg.sq_ds -= RTE_BE32(1);
3188 loc->mbuf = mbuf->next;
3189 rte_pktmbuf_free_seg(mbuf);
3195 rte_pktmbuf_mtod(loc->mbuf, uint8_t *),
3196 rte_pktmbuf_data_len(loc->mbuf), olx);
3197 txq->elts[txq->elts_head++ & txq->elts_m] = loc->mbuf;
3202 if ((uintptr_t)dseg >= (uintptr_t)txq->wqes_end)
3203 dseg = (struct mlx5_wqe_dseg *)txq->wqes;
3204 loc->mbuf = loc->mbuf->next;
3207 txq->wqe_ci += (ds + 3) / 4;
3208 loc->wqe_free -= (ds + 3) / 4;
3209 /* Request CQE generation if limits are reached. */
3210 mlx5_tx_request_completion(txq, loc, true, olx);
3211 return MLX5_TXCMP_CODE_MULTI;
3215 * Tx one packet function for multi-segment SEND. Supports all
3216 * types of Tx offloads, uses MLX5_OPCODE_SEND to build WQEs,
3217 * sends one packet per WQE, with data inlining in
3218 * Ethernet Segment and minimal Data Segments.
3220 * This routine is responsible for storing processed mbuf
3221 * into elts ring buffer and update elts_head.
3224 * Pointer to TX queue structure.
3226 * Pointer to burst routine local context.
3228 * Configured Tx offloads mask. It is fully defined at
3229 * compile time and may be used for optimization.
3232 * MLX5_TXCMP_CODE_EXIT - sending is done or impossible.
3233 * MLX5_TXCMP_CODE_ERROR - some unrecoverable error occurred.
3234 * Local context variables partially updated.
3236 static __rte_always_inline enum mlx5_txcmp_code
3237 mlx5_tx_packet_multi_inline(struct mlx5_txq_data *restrict txq,
3238 struct mlx5_txq_local *restrict loc,
3241 struct mlx5_wqe *restrict wqe;
3242 unsigned int ds, inlen, dlen, vlan = 0;
3244 assert(MLX5_TXOFF_CONFIG(INLINE));
3245 assert(NB_SEGS(loc->mbuf) > 1);
3247 * First calculate data length to be inlined
3248 * to estimate the required space for WQE.
3250 dlen = rte_pktmbuf_pkt_len(loc->mbuf);
3251 if (MLX5_TXOFF_CONFIG(VLAN) && loc->mbuf->ol_flags & PKT_TX_VLAN_PKT)
3252 vlan = sizeof(struct rte_vlan_hdr);
3253 inlen = dlen + vlan;
3254 /* Check against minimal length. */
3255 if (inlen <= MLX5_ESEG_MIN_INLINE_SIZE)
3256 return MLX5_TXCMP_CODE_ERROR;
3257 assert(txq->inlen_send >= MLX5_ESEG_MIN_INLINE_SIZE);
3258 if (inlen > txq->inlen_send) {
3259 struct rte_mbuf *mbuf;
3264 * Packet length exceeds the allowed inline
3265 * data length, check whether the minimal
3266 * inlining is required.
3268 if (txq->inlen_mode) {
3269 assert(txq->inlen_mode >= MLX5_ESEG_MIN_INLINE_SIZE);
3270 assert(txq->inlen_mode <= txq->inlen_send);
3271 inlen = txq->inlen_mode;
3273 if (!vlan || txq->vlan_en) {
3275 * VLAN insertion will be done inside by HW.
3276 * It is not utmost effective - VLAN flag is
3277 * checked twice, but we should proceed the
3278 * inlining length correctly and take into
3279 * account the VLAN header being inserted.
3281 return mlx5_tx_packet_multi_send
3284 inlen = MLX5_ESEG_MIN_INLINE_SIZE;
3287 * Now we know the minimal amount of data is requested
3288 * to inline. Check whether we should inline the buffers
3289 * from the chain beginning to eliminate some mbufs.
3292 nxlen = rte_pktmbuf_data_len(mbuf);
3293 if (unlikely(nxlen <= txq->inlen_send)) {
3294 /* We can inline first mbuf at least. */
3295 if (nxlen < inlen) {
3298 /* Scan mbufs till inlen filled. */
3303 nxlen = rte_pktmbuf_data_len(mbuf);
3305 } while (unlikely(nxlen < inlen));
3306 if (unlikely(nxlen > txq->inlen_send)) {
3307 /* We cannot inline entire mbuf. */
3308 smlen = inlen - smlen;
3309 start = rte_pktmbuf_mtod_offset
3310 (mbuf, uintptr_t, smlen);
3317 /* There should be not end of packet. */
3319 nxlen = inlen + rte_pktmbuf_data_len(mbuf);
3320 } while (unlikely(nxlen < txq->inlen_send));
3322 start = rte_pktmbuf_mtod(mbuf, uintptr_t);
3324 * Check whether we can do inline to align start
3325 * address of data buffer to cacheline.
3328 start = (~start + 1) & (RTE_CACHE_LINE_SIZE - 1);
3329 if (unlikely(start)) {
3331 if (start <= txq->inlen_send)
3336 * Check whether there are enough free WQEBBs:
3338 * - Ethernet Segment
3339 * - First Segment of inlined Ethernet data
3340 * - ... data continued ...
3341 * - Data Segments of pointer/min inline type
3343 * Estimate the number of Data Segments conservatively,
3344 * supposing no any mbufs is being freed during inlining.
3346 assert(inlen <= txq->inlen_send);
3347 ds = NB_SEGS(loc->mbuf) + 2 + (inlen -
3348 MLX5_ESEG_MIN_INLINE_SIZE +
3350 MLX5_WSEG_SIZE - 1) / MLX5_WSEG_SIZE;
3351 if (unlikely(loc->wqe_free < ((ds + 3) / 4)))
3352 return MLX5_TXCMP_CODE_EXIT;
3353 /* Check for maximal WQE size. */
3354 if (unlikely((MLX5_WQE_SIZE_MAX / MLX5_WSEG_SIZE) < ((ds + 3) / 4)))
3355 return MLX5_TXCMP_CODE_ERROR;
3356 #ifdef MLX5_PMD_SOFT_COUNTERS
3357 /* Update sent data bytes/packets counters. */
3358 txq->stats.obytes += dlen + vlan;
3360 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
3361 loc->wqe_last = wqe;
3362 mlx5_tx_cseg_init(txq, loc, wqe, 0, MLX5_OPCODE_SEND, olx);
3363 ds = mlx5_tx_mseg_build(txq, loc, wqe, vlan, inlen, 0, olx);
3364 wqe->cseg.sq_ds = rte_cpu_to_be_32(txq->qp_num_8s | ds);
3365 txq->wqe_ci += (ds + 3) / 4;
3366 loc->wqe_free -= (ds + 3) / 4;
3367 /* Request CQE generation if limits are reached. */
3368 mlx5_tx_request_completion(txq, loc, true, olx);
3369 return MLX5_TXCMP_CODE_MULTI;
3373 * Tx burst function for multi-segment packets. Supports all
3374 * types of Tx offloads, uses MLX5_OPCODE_SEND/TSO to build WQEs,
3375 * sends one packet per WQE. Function stops sending if it
3376 * encounters the single-segment packet.
3378 * This routine is responsible for storing processed mbuf
3379 * into elts ring buffer and update elts_head.
3382 * Pointer to TX queue structure.
3384 * Packets to transmit.
3386 * Number of packets in array.
3388 * Pointer to burst routine local context.
3390 * Configured Tx offloads mask. It is fully defined at
3391 * compile time and may be used for optimization.
3394 * MLX5_TXCMP_CODE_EXIT - sending is done or impossible.
3395 * MLX5_TXCMP_CODE_ERROR - some unrecoverable error occurred.
3396 * MLX5_TXCMP_CODE_SINGLE - single-segment packet encountered.
3397 * MLX5_TXCMP_CODE_TSO - TSO single-segment packet encountered.
3398 * Local context variables updated.
3400 static __rte_always_inline enum mlx5_txcmp_code
3401 mlx5_tx_burst_mseg(struct mlx5_txq_data *restrict txq,
3402 struct rte_mbuf **restrict pkts,
3403 unsigned int pkts_n,
3404 struct mlx5_txq_local *restrict loc,
3407 assert(loc->elts_free && loc->wqe_free);
3408 assert(pkts_n > loc->pkts_sent);
3409 pkts += loc->pkts_sent + 1;
3410 pkts_n -= loc->pkts_sent;
3412 enum mlx5_txcmp_code ret;
3414 assert(NB_SEGS(loc->mbuf) > 1);
3416 * Estimate the number of free elts quickly but
3417 * conservatively. Some segment may be fully inlined
3418 * and freed, ignore this here - precise estimation
3421 if (loc->elts_free < NB_SEGS(loc->mbuf))
3422 return MLX5_TXCMP_CODE_EXIT;
3423 if (MLX5_TXOFF_CONFIG(TSO) &&
3424 unlikely(loc->mbuf->ol_flags & PKT_TX_TCP_SEG)) {
3425 /* Proceed with multi-segment TSO. */
3426 ret = mlx5_tx_packet_multi_tso(txq, loc, olx);
3427 } else if (MLX5_TXOFF_CONFIG(INLINE)) {
3428 /* Proceed with multi-segment SEND with inlining. */
3429 ret = mlx5_tx_packet_multi_inline(txq, loc, olx);
3431 /* Proceed with multi-segment SEND w/o inlining. */
3432 ret = mlx5_tx_packet_multi_send(txq, loc, olx);
3434 if (ret == MLX5_TXCMP_CODE_EXIT)
3435 return MLX5_TXCMP_CODE_EXIT;
3436 if (ret == MLX5_TXCMP_CODE_ERROR)
3437 return MLX5_TXCMP_CODE_ERROR;
3438 /* WQE is built, go to the next packet. */
3441 if (unlikely(!pkts_n || !loc->elts_free || !loc->wqe_free))
3442 return MLX5_TXCMP_CODE_EXIT;
3443 loc->mbuf = *pkts++;
3445 rte_prefetch0(*pkts);
3446 if (likely(NB_SEGS(loc->mbuf) > 1))
3448 /* Here ends the series of multi-segment packets. */
3449 if (MLX5_TXOFF_CONFIG(TSO) &&
3450 unlikely(loc->mbuf->ol_flags & PKT_TX_TCP_SEG))
3451 return MLX5_TXCMP_CODE_TSO;
3452 return MLX5_TXCMP_CODE_SINGLE;
3458 * Tx burst function for single-segment packets with TSO.
3459 * Supports all types of Tx offloads, except multi-packets.
3460 * Uses MLX5_OPCODE_TSO to build WQEs, sends one packet per WQE.
3461 * Function stops sending if it encounters the multi-segment
3462 * packet or packet without TSO requested.
3464 * The routine is responsible for storing processed mbuf
3465 * into elts ring buffer and update elts_head if inline
3466 * offloads is requested due to possible early freeing
3467 * of the inlined mbufs (can not store pkts array in elts
3471 * Pointer to TX queue structure.
3473 * Packets to transmit.
3475 * Number of packets in array.
3477 * Pointer to burst routine local context.
3479 * Configured Tx offloads mask. It is fully defined at
3480 * compile time and may be used for optimization.
3483 * MLX5_TXCMP_CODE_EXIT - sending is done or impossible.
3484 * MLX5_TXCMP_CODE_ERROR - some unrecoverable error occurred.
3485 * MLX5_TXCMP_CODE_SINGLE - single-segment packet encountered.
3486 * MLX5_TXCMP_CODE_MULTI - multi-segment packet encountered.
3487 * Local context variables updated.
3489 static __rte_always_inline enum mlx5_txcmp_code
3490 mlx5_tx_burst_tso(struct mlx5_txq_data *restrict txq,
3491 struct rte_mbuf **restrict pkts,
3492 unsigned int pkts_n,
3493 struct mlx5_txq_local *restrict loc,
3496 assert(loc->elts_free && loc->wqe_free);
3497 assert(pkts_n > loc->pkts_sent);
3498 pkts += loc->pkts_sent + 1;
3499 pkts_n -= loc->pkts_sent;
3501 struct mlx5_wqe_dseg *restrict dseg;
3502 struct mlx5_wqe *restrict wqe;
3503 unsigned int ds, dlen, hlen, ntcp, vlan = 0;
3506 assert(NB_SEGS(loc->mbuf) == 1);
3507 dlen = rte_pktmbuf_data_len(loc->mbuf);
3508 if (MLX5_TXOFF_CONFIG(VLAN) &&
3509 loc->mbuf->ol_flags & PKT_TX_VLAN_PKT) {
3510 vlan = sizeof(struct rte_vlan_hdr);
3513 * First calculate the WQE size to check
3514 * whether we have enough space in ring buffer.
3516 hlen = loc->mbuf->l2_len + vlan +
3517 loc->mbuf->l3_len + loc->mbuf->l4_len;
3518 if (unlikely((!hlen || !loc->mbuf->tso_segsz)))
3519 return MLX5_TXCMP_CODE_ERROR;
3520 if (loc->mbuf->ol_flags & PKT_TX_TUNNEL_MASK)
3521 hlen += loc->mbuf->outer_l2_len +
3522 loc->mbuf->outer_l3_len;
3523 /* Segment must contain all TSO headers. */
3524 if (unlikely(hlen > MLX5_MAX_TSO_HEADER ||
3525 hlen <= MLX5_ESEG_MIN_INLINE_SIZE ||
3526 hlen > (dlen + vlan)))
3527 return MLX5_TXCMP_CODE_ERROR;
3529 * Check whether there are enough free WQEBBs:
3531 * - Ethernet Segment
3532 * - First Segment of inlined Ethernet data
3533 * - ... data continued ...
3534 * - Finishing Data Segment of pointer type
3536 ds = 4 + (hlen - MLX5_ESEG_MIN_INLINE_SIZE +
3537 MLX5_WSEG_SIZE - 1) / MLX5_WSEG_SIZE;
3538 if (loc->wqe_free < ((ds + 3) / 4))
3539 return MLX5_TXCMP_CODE_EXIT;
3540 #ifdef MLX5_PMD_SOFT_COUNTERS
3541 /* Update sent data bytes/packets counters. */
3542 ntcp = (dlen + vlan - hlen +
3543 loc->mbuf->tso_segsz - 1) /
3544 loc->mbuf->tso_segsz;
3546 * One will be added for mbuf itself at the end
3547 * of the mlx5_tx_burst from loc->pkts_sent field.
3550 txq->stats.opackets += ntcp;
3551 txq->stats.obytes += dlen + vlan + ntcp * hlen;
3554 * Build the TSO WQE:
3556 * - Ethernet Segment with hlen bytes inlined
3557 * - Data Segment of pointer type
3559 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
3560 loc->wqe_last = wqe;
3561 mlx5_tx_cseg_init(txq, loc, wqe, ds,
3562 MLX5_OPCODE_TSO, olx);
3563 dseg = mlx5_tx_eseg_data(txq, loc, wqe, vlan, hlen, 1, olx);
3564 dptr = rte_pktmbuf_mtod(loc->mbuf, uint8_t *) + hlen - vlan;
3565 dlen -= hlen - vlan;
3566 mlx5_tx_dseg_ptr(txq, loc, dseg, dptr, dlen, olx);
3568 * WQE is built, update the loop parameters
3569 * and go to the next packet.
3571 txq->wqe_ci += (ds + 3) / 4;
3572 loc->wqe_free -= (ds + 3) / 4;
3573 if (MLX5_TXOFF_CONFIG(INLINE))
3574 txq->elts[txq->elts_head++ & txq->elts_m] = loc->mbuf;
3578 /* Request CQE generation if limits are reached. */
3579 mlx5_tx_request_completion(txq, loc, false, olx);
3580 if (unlikely(!pkts_n || !loc->elts_free || !loc->wqe_free))
3581 return MLX5_TXCMP_CODE_EXIT;
3582 loc->mbuf = *pkts++;
3584 rte_prefetch0(*pkts);
3585 if (MLX5_TXOFF_CONFIG(MULTI) &&
3586 unlikely(NB_SEGS(loc->mbuf) > 1))
3587 return MLX5_TXCMP_CODE_MULTI;
3588 if (likely(!(loc->mbuf->ol_flags & PKT_TX_TCP_SEG)))
3589 return MLX5_TXCMP_CODE_SINGLE;
3590 /* Continue with the next TSO packet. */
3596 * Analyze the packet and select the best method to send.
3599 * Pointer to TX queue structure.
3601 * Pointer to burst routine local context.
3603 * Configured Tx offloads mask. It is fully defined at
3604 * compile time and may be used for optimization.
3606 * The predefined flag whether do complete check for
3607 * multi-segment packets and TSO.
3610 * MLX5_TXCMP_CODE_MULTI - multi-segment packet encountered.
3611 * MLX5_TXCMP_CODE_TSO - TSO required, use TSO/LSO.
3612 * MLX5_TXCMP_CODE_SINGLE - single-segment packet, use SEND.
3613 * MLX5_TXCMP_CODE_EMPW - single-segment packet, use MPW.
3615 static __rte_always_inline enum mlx5_txcmp_code
3616 mlx5_tx_able_to_empw(struct mlx5_txq_data *restrict txq,
3617 struct mlx5_txq_local *restrict loc,
3621 /* Check for multi-segment packet. */
3623 MLX5_TXOFF_CONFIG(MULTI) &&
3624 unlikely(NB_SEGS(loc->mbuf) > 1))
3625 return MLX5_TXCMP_CODE_MULTI;
3626 /* Check for TSO packet. */
3628 MLX5_TXOFF_CONFIG(TSO) &&
3629 unlikely(loc->mbuf->ol_flags & PKT_TX_TCP_SEG))
3630 return MLX5_TXCMP_CODE_TSO;
3631 /* Check if eMPW is enabled at all. */
3632 if (!MLX5_TXOFF_CONFIG(EMPW))
3633 return MLX5_TXCMP_CODE_SINGLE;
3634 /* Check if eMPW can be engaged. */
3635 if (MLX5_TXOFF_CONFIG(VLAN) &&
3636 unlikely(loc->mbuf->ol_flags & PKT_TX_VLAN_PKT) &&
3637 (!MLX5_TXOFF_CONFIG(INLINE) ||
3638 unlikely((rte_pktmbuf_data_len(loc->mbuf) +
3639 sizeof(struct rte_vlan_hdr)) > txq->inlen_empw))) {
3641 * eMPW does not support VLAN insertion offload,
3642 * we have to inline the entire packet but
3643 * packet is too long for inlining.
3645 return MLX5_TXCMP_CODE_SINGLE;
3647 return MLX5_TXCMP_CODE_EMPW;
3651 * Check the next packet attributes to match with the eMPW batch ones.
3654 * Pointer to TX queue structure.
3656 * Pointer to Ethernet Segment of eMPW batch.
3658 * Pointer to burst routine local context.
3660 * Configured Tx offloads mask. It is fully defined at
3661 * compile time and may be used for optimization.
3664 * true - packet match with eMPW batch attributes.
3665 * false - no match, eMPW should be restarted.
3667 static __rte_always_inline bool
3668 mlx5_tx_match_empw(struct mlx5_txq_data *restrict txq __rte_unused,
3669 struct mlx5_wqe_eseg *restrict es,
3670 struct mlx5_txq_local *restrict loc,
3673 uint8_t swp_flags = 0;
3675 /* Compare the checksum flags, if any. */
3676 if (MLX5_TXOFF_CONFIG(CSUM) &&
3677 txq_ol_cksum_to_cs(loc->mbuf) != es->cs_flags)
3679 /* Compare the Software Parser offsets and flags. */
3680 if (MLX5_TXOFF_CONFIG(SWP) &&
3681 (es->swp_offs != txq_mbuf_to_swp(loc, &swp_flags, olx) ||
3682 es->swp_flags != swp_flags))
3684 /* Fill metadata field if needed. */
3685 if (MLX5_TXOFF_CONFIG(METADATA) &&
3686 es->metadata != (loc->mbuf->ol_flags & PKT_TX_METADATA ?
3687 loc->mbuf->tx_metadata : 0))
3689 /* There must be no VLAN packets in eMPW loop. */
3690 if (MLX5_TXOFF_CONFIG(VLAN))
3691 assert(!(loc->mbuf->ol_flags & PKT_TX_VLAN_PKT));
3696 * Update send loop variables and WQE for eMPW loop
3697 * without data inlining. Number of Data Segments is
3698 * equal to the number of sent packets.
3701 * Pointer to TX queue structure.
3703 * Pointer to burst routine local context.
3705 * Number of packets/Data Segments/Packets.
3707 * Accumulated statistics, bytes sent
3709 * Configured Tx offloads mask. It is fully defined at
3710 * compile time and may be used for optimization.
3713 * true - packet match with eMPW batch attributes.
3714 * false - no match, eMPW should be restarted.
3716 static __rte_always_inline void
3717 mlx5_tx_sdone_empw(struct mlx5_txq_data *restrict txq,
3718 struct mlx5_txq_local *restrict loc,
3723 assert(!MLX5_TXOFF_CONFIG(INLINE));
3724 #ifdef MLX5_PMD_SOFT_COUNTERS
3725 /* Update sent data bytes counter. */
3726 txq->stats.obytes += slen;
3730 loc->elts_free -= ds;
3731 loc->pkts_sent += ds;
3733 loc->wqe_last->cseg.sq_ds = rte_cpu_to_be_32(txq->qp_num_8s | ds);
3734 txq->wqe_ci += (ds + 3) / 4;
3735 loc->wqe_free -= (ds + 3) / 4;
3736 /* Request CQE generation if limits are reached. */
3737 mlx5_tx_request_completion(txq, loc, false, olx);
3741 * Update send loop variables and WQE for eMPW loop
3742 * with data inlining. Gets the size of pushed descriptors
3743 * and data to the WQE.
3746 * Pointer to TX queue structure.
3748 * Pointer to burst routine local context.
3750 * Total size of descriptor/data in bytes.
3752 * Accumulated statistics, data bytes sent.
3754 * Configured Tx offloads mask. It is fully defined at
3755 * compile time and may be used for optimization.
3758 * true - packet match with eMPW batch attributes.
3759 * false - no match, eMPW should be restarted.
3761 static __rte_always_inline void
3762 mlx5_tx_idone_empw(struct mlx5_txq_data *restrict txq,
3763 struct mlx5_txq_local *restrict loc,
3766 unsigned int olx __rte_unused)
3768 assert(MLX5_TXOFF_CONFIG(INLINE));
3769 assert((len % MLX5_WSEG_SIZE) == 0);
3770 #ifdef MLX5_PMD_SOFT_COUNTERS
3771 /* Update sent data bytes counter. */
3772 txq->stats.obytes += slen;
3776 len = len / MLX5_WSEG_SIZE + 2;
3777 loc->wqe_last->cseg.sq_ds = rte_cpu_to_be_32(txq->qp_num_8s | len);
3778 txq->wqe_ci += (len + 3) / 4;
3779 loc->wqe_free -= (len + 3) / 4;
3780 /* Request CQE generation if limits are reached. */
3781 mlx5_tx_request_completion(txq, loc, false, olx);
3785 * The set of Tx burst functions for single-segment packets
3786 * without TSO and with Multi-Packet Writing feature support.
3787 * Supports all types of Tx offloads, except multi-packets
3790 * Uses MLX5_OPCODE_EMPW to build WQEs if possible and sends
3791 * as many packet per WQE as it can. If eMPW is not configured
3792 * or packet can not be sent with eMPW (VLAN insertion) the
3793 * ordinary SEND opcode is used and only one packet placed
3796 * Functions stop sending if it encounters the multi-segment
3797 * packet or packet with TSO requested.
3799 * The routines are responsible for storing processed mbuf
3800 * into elts ring buffer and update elts_head if inlining
3801 * offload is requested. Otherwise the copying mbufs to elts
3802 * can be postponed and completed at the end of burst routine.
3805 * Pointer to TX queue structure.
3807 * Packets to transmit.
3809 * Number of packets in array.
3811 * Pointer to burst routine local context.
3813 * Configured Tx offloads mask. It is fully defined at
3814 * compile time and may be used for optimization.
3817 * MLX5_TXCMP_CODE_EXIT - sending is done or impossible.
3818 * MLX5_TXCMP_CODE_ERROR - some unrecoverable error occurred.
3819 * MLX5_TXCMP_CODE_MULTI - multi-segment packet encountered.
3820 * MLX5_TXCMP_CODE_TSO - TSO packet encountered.
3821 * MLX5_TXCMP_CODE_SINGLE - used inside functions set.
3822 * MLX5_TXCMP_CODE_EMPW - used inside functions set.
3824 * Local context variables updated.
3827 * The routine sends packets with MLX5_OPCODE_EMPW
3828 * without inlining, this is dedicated optimized branch.
3829 * No VLAN insertion is supported.
3831 static __rte_always_inline enum mlx5_txcmp_code
3832 mlx5_tx_burst_empw_simple(struct mlx5_txq_data *restrict txq,
3833 struct rte_mbuf **restrict pkts,
3834 unsigned int pkts_n,
3835 struct mlx5_txq_local *restrict loc,
3839 * Subroutine is the part of mlx5_tx_burst_single()
3840 * and sends single-segment packet with eMPW opcode
3841 * without data inlining.
3843 assert(!MLX5_TXOFF_CONFIG(INLINE));
3844 assert(MLX5_TXOFF_CONFIG(EMPW));
3845 assert(loc->elts_free && loc->wqe_free);
3846 assert(pkts_n > loc->pkts_sent);
3847 static_assert(MLX5_EMPW_MIN_PACKETS >= 2, "invalid min size");
3848 pkts += loc->pkts_sent + 1;
3849 pkts_n -= loc->pkts_sent;
3851 struct mlx5_wqe_dseg *restrict dseg;
3852 struct mlx5_wqe_eseg *restrict eseg;
3853 enum mlx5_txcmp_code ret;
3854 unsigned int part, loop;
3855 unsigned int slen = 0;
3858 part = RTE_MIN(pkts_n, MLX5_EMPW_MAX_PACKETS);
3859 if (unlikely(loc->elts_free < part)) {
3860 /* We have no enough elts to save all mbufs. */
3861 if (unlikely(loc->elts_free < MLX5_EMPW_MIN_PACKETS))
3862 return MLX5_TXCMP_CODE_EXIT;
3863 /* But we still able to send at least minimal eMPW. */
3864 part = loc->elts_free;
3866 /* Check whether we have enough WQEs */
3867 if (unlikely(loc->wqe_free < ((2 + part + 3) / 4))) {
3868 if (unlikely(loc->wqe_free <
3869 ((2 + MLX5_EMPW_MIN_PACKETS + 3) / 4)))
3870 return MLX5_TXCMP_CODE_EXIT;
3871 part = (loc->wqe_free * 4) - 2;
3873 if (likely(part > 1))
3874 rte_prefetch0(*pkts);
3875 loc->wqe_last = txq->wqes + (txq->wqe_ci & txq->wqe_m);
3877 * Build eMPW title WQEBB:
3878 * - Control Segment, eMPW opcode
3879 * - Ethernet Segment, no inline
3881 mlx5_tx_cseg_init(txq, loc, loc->wqe_last, part + 2,
3882 MLX5_OPCODE_ENHANCED_MPSW, olx);
3883 mlx5_tx_eseg_none(txq, loc, loc->wqe_last,
3884 olx & ~MLX5_TXOFF_CONFIG_VLAN);
3885 eseg = &loc->wqe_last->eseg;
3886 dseg = &loc->wqe_last->dseg[0];
3889 uint32_t dlen = rte_pktmbuf_data_len(loc->mbuf);
3890 #ifdef MLX5_PMD_SOFT_COUNTERS
3891 /* Update sent data bytes counter. */
3896 rte_pktmbuf_mtod(loc->mbuf, uint8_t *),
3898 if (unlikely(--loop == 0))
3900 loc->mbuf = *pkts++;
3901 if (likely(loop > 1))
3902 rte_prefetch0(*pkts);
3903 ret = mlx5_tx_able_to_empw(txq, loc, olx, true);
3905 * Unroll the completion code to avoid
3906 * returning variable value - it results in
3907 * unoptimized sequent checking in caller.
3909 if (ret == MLX5_TXCMP_CODE_MULTI) {
3911 mlx5_tx_sdone_empw(txq, loc, part, slen, olx);
3912 if (unlikely(!loc->elts_free ||
3914 return MLX5_TXCMP_CODE_EXIT;
3915 return MLX5_TXCMP_CODE_MULTI;
3917 if (ret == MLX5_TXCMP_CODE_TSO) {
3919 mlx5_tx_sdone_empw(txq, loc, part, slen, olx);
3920 if (unlikely(!loc->elts_free ||
3922 return MLX5_TXCMP_CODE_EXIT;
3923 return MLX5_TXCMP_CODE_TSO;
3925 if (ret == MLX5_TXCMP_CODE_SINGLE) {
3927 mlx5_tx_sdone_empw(txq, loc, part, slen, olx);
3928 if (unlikely(!loc->elts_free ||
3930 return MLX5_TXCMP_CODE_EXIT;
3931 return MLX5_TXCMP_CODE_SINGLE;
3933 if (ret != MLX5_TXCMP_CODE_EMPW) {
3936 mlx5_tx_sdone_empw(txq, loc, part, slen, olx);
3937 return MLX5_TXCMP_CODE_ERROR;
3940 * Check whether packet parameters coincide
3941 * within assumed eMPW batch:
3942 * - check sum settings
3944 * - software parser settings
3946 if (!mlx5_tx_match_empw(txq, eseg, loc, olx)) {
3949 mlx5_tx_sdone_empw(txq, loc, part, slen, olx);
3950 if (unlikely(!loc->elts_free ||
3952 return MLX5_TXCMP_CODE_EXIT;
3956 /* Packet attributes match, continue the same eMPW. */
3958 if ((uintptr_t)dseg >= (uintptr_t)txq->wqes_end)
3959 dseg = (struct mlx5_wqe_dseg *)txq->wqes;
3961 /* eMPW is built successfully, update loop parameters. */
3963 assert(pkts_n >= part);
3964 #ifdef MLX5_PMD_SOFT_COUNTERS
3965 /* Update sent data bytes counter. */
3966 txq->stats.obytes += slen;
3968 loc->elts_free -= part;
3969 loc->pkts_sent += part;
3970 txq->wqe_ci += (2 + part + 3) / 4;
3971 loc->wqe_free -= (2 + part + 3) / 4;
3973 /* Request CQE generation if limits are reached. */
3974 mlx5_tx_request_completion(txq, loc, false, olx);
3975 if (unlikely(!pkts_n || !loc->elts_free || !loc->wqe_free))
3976 return MLX5_TXCMP_CODE_EXIT;
3977 loc->mbuf = *pkts++;
3978 ret = mlx5_tx_able_to_empw(txq, loc, olx, true);
3979 if (unlikely(ret != MLX5_TXCMP_CODE_EMPW))
3981 /* Continue sending eMPW batches. */
3987 * The routine sends packets with MLX5_OPCODE_EMPW
3988 * with inlining, optionally supports VLAN insertion.
3990 static __rte_always_inline enum mlx5_txcmp_code
3991 mlx5_tx_burst_empw_inline(struct mlx5_txq_data *restrict txq,
3992 struct rte_mbuf **restrict pkts,
3993 unsigned int pkts_n,
3994 struct mlx5_txq_local *restrict loc,
3998 * Subroutine is the part of mlx5_tx_burst_single()
3999 * and sends single-segment packet with eMPW opcode
4000 * with data inlining.
4002 assert(MLX5_TXOFF_CONFIG(INLINE));
4003 assert(MLX5_TXOFF_CONFIG(EMPW));
4004 assert(loc->elts_free && loc->wqe_free);
4005 assert(pkts_n > loc->pkts_sent);
4006 static_assert(MLX5_EMPW_MIN_PACKETS >= 2, "invalid min size");
4007 pkts += loc->pkts_sent + 1;
4008 pkts_n -= loc->pkts_sent;
4010 struct mlx5_wqe_dseg *restrict dseg;
4011 struct mlx5_wqe_eseg *restrict eseg;
4012 enum mlx5_txcmp_code ret;
4013 unsigned int room, part, nlim;
4014 unsigned int slen = 0;
4017 * Limits the amount of packets in one WQE
4018 * to improve CQE latency generation.
4020 nlim = RTE_MIN(pkts_n, MLX5_EMPW_MAX_PACKETS);
4021 /* Check whether we have minimal amount WQEs */
4022 if (unlikely(loc->wqe_free <
4023 ((2 + MLX5_EMPW_MIN_PACKETS + 3) / 4)))
4024 return MLX5_TXCMP_CODE_EXIT;
4025 if (likely(pkts_n > 1))
4026 rte_prefetch0(*pkts);
4027 loc->wqe_last = txq->wqes + (txq->wqe_ci & txq->wqe_m);
4029 * Build eMPW title WQEBB:
4030 * - Control Segment, eMPW opcode, zero DS
4031 * - Ethernet Segment, no inline
4033 mlx5_tx_cseg_init(txq, loc, loc->wqe_last, 0,
4034 MLX5_OPCODE_ENHANCED_MPSW, olx);
4035 mlx5_tx_eseg_none(txq, loc, loc->wqe_last,
4036 olx & ~MLX5_TXOFF_CONFIG_VLAN);
4037 eseg = &loc->wqe_last->eseg;
4038 dseg = &loc->wqe_last->dseg[0];
4039 room = RTE_MIN(MLX5_WQE_SIZE_MAX / MLX5_WQE_SIZE,
4040 loc->wqe_free) * MLX5_WQE_SIZE -
4041 MLX5_WQE_CSEG_SIZE -
4043 /* Build WQE till we have space, packets and resources. */
4046 uint32_t dlen = rte_pktmbuf_data_len(loc->mbuf);
4047 uint8_t *dptr = rte_pktmbuf_mtod(loc->mbuf, uint8_t *);
4050 assert(room >= MLX5_WQE_DSEG_SIZE);
4051 assert((room % MLX5_WQE_DSEG_SIZE) == 0);
4052 assert((uintptr_t)dseg < (uintptr_t)txq->wqes_end);
4054 * Some Tx offloads may cause an error if
4055 * packet is not long enough, check against
4056 * assumed minimal length.
4058 if (unlikely(dlen <= MLX5_ESEG_MIN_INLINE_SIZE)) {
4060 if (unlikely(!part))
4061 return MLX5_TXCMP_CODE_ERROR;
4063 * We have some successfully built
4064 * packet Data Segments to send.
4066 mlx5_tx_idone_empw(txq, loc, part, slen, olx);
4067 return MLX5_TXCMP_CODE_ERROR;
4069 /* Inline or not inline - that's the Question. */
4070 if (dlen > txq->inlen_empw)
4072 /* Inline entire packet, optional VLAN insertion. */
4073 tlen = sizeof(dseg->bcount) + dlen;
4074 if (MLX5_TXOFF_CONFIG(VLAN) &&
4075 loc->mbuf->ol_flags & PKT_TX_VLAN_PKT) {
4077 * The packet length must be checked in
4078 * mlx5_tx_able_to_empw() and packet
4079 * fits into inline length guaranteed.
4081 assert((dlen + sizeof(struct rte_vlan_hdr)) <=
4083 tlen += sizeof(struct rte_vlan_hdr);
4086 dseg = mlx5_tx_dseg_vlan(txq, loc, dseg,
4088 #ifdef MLX5_PMD_SOFT_COUNTERS
4089 /* Update sent data bytes counter. */
4090 slen += sizeof(struct rte_vlan_hdr);
4095 dseg = mlx5_tx_dseg_empw(txq, loc, dseg,
4098 tlen = RTE_ALIGN(tlen, MLX5_WSEG_SIZE);
4099 assert(room >= tlen);
4102 * Packet data are completely inlined,
4103 * free the packet immediately.
4105 rte_pktmbuf_free_seg(loc->mbuf);
4109 * Not inlinable VLAN packets are
4110 * proceeded outside of this routine.
4112 assert(room >= MLX5_WQE_DSEG_SIZE);
4113 if (MLX5_TXOFF_CONFIG(VLAN))
4114 assert(!(loc->mbuf->ol_flags &
4116 mlx5_tx_dseg_ptr(txq, loc, dseg, dptr, dlen, olx);
4117 /* We have to store mbuf in elts.*/
4118 txq->elts[txq->elts_head++ & txq->elts_m] = loc->mbuf;
4119 room -= MLX5_WQE_DSEG_SIZE;
4120 /* Ring buffer wraparound is checked at the loop end.*/
4123 #ifdef MLX5_PMD_SOFT_COUNTERS
4124 /* Update sent data bytes counter. */
4130 if (unlikely(!pkts_n || !loc->elts_free)) {
4132 * We have no resources/packets to
4133 * continue build descriptors.
4136 mlx5_tx_idone_empw(txq, loc, part, slen, olx);
4137 return MLX5_TXCMP_CODE_EXIT;
4139 loc->mbuf = *pkts++;
4140 if (likely(pkts_n > 1))
4141 rte_prefetch0(*pkts);
4142 ret = mlx5_tx_able_to_empw(txq, loc, olx, true);
4144 * Unroll the completion code to avoid
4145 * returning variable value - it results in
4146 * unoptimized sequent checking in caller.
4148 if (ret == MLX5_TXCMP_CODE_MULTI) {
4150 mlx5_tx_idone_empw(txq, loc, part, slen, olx);
4151 if (unlikely(!loc->elts_free ||
4153 return MLX5_TXCMP_CODE_EXIT;
4154 return MLX5_TXCMP_CODE_MULTI;
4156 if (ret == MLX5_TXCMP_CODE_TSO) {
4158 mlx5_tx_idone_empw(txq, loc, part, slen, olx);
4159 if (unlikely(!loc->elts_free ||
4161 return MLX5_TXCMP_CODE_EXIT;
4162 return MLX5_TXCMP_CODE_TSO;
4164 if (ret == MLX5_TXCMP_CODE_SINGLE) {
4166 mlx5_tx_idone_empw(txq, loc, part, slen, olx);
4167 if (unlikely(!loc->elts_free ||
4169 return MLX5_TXCMP_CODE_EXIT;
4170 return MLX5_TXCMP_CODE_SINGLE;
4172 if (ret != MLX5_TXCMP_CODE_EMPW) {
4175 mlx5_tx_idone_empw(txq, loc, part, slen, olx);
4176 return MLX5_TXCMP_CODE_ERROR;
4178 /* Check if we have minimal room left. */
4180 if (unlikely(!nlim || room < MLX5_WQE_DSEG_SIZE))
4183 * Check whether packet parameters coincide
4184 * within assumed eMPW batch:
4185 * - check sum settings
4187 * - software parser settings
4189 if (!mlx5_tx_match_empw(txq, eseg, loc, olx))
4191 /* Packet attributes match, continue the same eMPW. */
4192 if ((uintptr_t)dseg >= (uintptr_t)txq->wqes_end)
4193 dseg = (struct mlx5_wqe_dseg *)txq->wqes;
4196 * We get here to close an existing eMPW
4197 * session and start the new one.
4201 if (unlikely(!part))
4202 return MLX5_TXCMP_CODE_EXIT;
4203 mlx5_tx_idone_empw(txq, loc, part, slen, olx);
4204 if (unlikely(!loc->elts_free ||
4206 return MLX5_TXCMP_CODE_EXIT;
4207 /* Continue the loop with new eMPW session. */
4213 * The routine sends packets with ordinary MLX5_OPCODE_SEND.
4214 * Data inlining and VLAN insertion are supported.
4216 static __rte_always_inline enum mlx5_txcmp_code
4217 mlx5_tx_burst_single_send(struct mlx5_txq_data *restrict txq,
4218 struct rte_mbuf **restrict pkts,
4219 unsigned int pkts_n,
4220 struct mlx5_txq_local *restrict loc,
4224 * Subroutine is the part of mlx5_tx_burst_single()
4225 * and sends single-segment packet with SEND opcode.
4227 assert(loc->elts_free && loc->wqe_free);
4228 assert(pkts_n > loc->pkts_sent);
4229 pkts += loc->pkts_sent + 1;
4230 pkts_n -= loc->pkts_sent;
4232 struct mlx5_wqe *restrict wqe;
4233 enum mlx5_txcmp_code ret;
4235 assert(NB_SEGS(loc->mbuf) == 1);
4236 if (MLX5_TXOFF_CONFIG(INLINE)) {
4237 unsigned int inlen, vlan = 0;
4239 inlen = rte_pktmbuf_data_len(loc->mbuf);
4240 if (MLX5_TXOFF_CONFIG(VLAN) &&
4241 loc->mbuf->ol_flags & PKT_TX_VLAN_PKT) {
4242 vlan = sizeof(struct rte_vlan_hdr);
4244 static_assert((sizeof(struct rte_vlan_hdr) +
4245 sizeof(struct rte_ether_hdr)) ==
4246 MLX5_ESEG_MIN_INLINE_SIZE,
4247 "invalid min inline data size");
4250 * If inlining is enabled at configuration time
4251 * the limit must be not less than minimal size.
4252 * Otherwise we would do extra check for data
4253 * size to avoid crashes due to length overflow.
4255 assert(txq->inlen_send >= MLX5_ESEG_MIN_INLINE_SIZE);
4256 if (inlen <= txq->inlen_send) {
4257 unsigned int seg_n, wqe_n;
4259 rte_prefetch0(rte_pktmbuf_mtod
4260 (loc->mbuf, uint8_t *));
4261 /* Check against minimal length. */
4262 if (inlen <= MLX5_ESEG_MIN_INLINE_SIZE)
4263 return MLX5_TXCMP_CODE_ERROR;
4265 * Completely inlined packet data WQE:
4266 * - Control Segment, SEND opcode
4267 * - Ethernet Segment, no VLAN insertion
4268 * - Data inlined, VLAN optionally inserted
4269 * - Alignment to MLX5_WSEG_SIZE
4270 * Have to estimate amount of WQEBBs
4272 seg_n = (inlen + 3 * MLX5_WSEG_SIZE -
4273 MLX5_ESEG_MIN_INLINE_SIZE +
4274 MLX5_WSEG_SIZE - 1) / MLX5_WSEG_SIZE;
4275 /* Check if there are enough WQEBBs. */
4276 wqe_n = (seg_n + 3) / 4;
4277 if (wqe_n > loc->wqe_free)
4278 return MLX5_TXCMP_CODE_EXIT;
4279 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
4280 loc->wqe_last = wqe;
4281 mlx5_tx_cseg_init(txq, loc, wqe, seg_n,
4282 MLX5_OPCODE_SEND, olx);
4283 mlx5_tx_eseg_data(txq, loc, wqe,
4284 vlan, inlen, 0, olx);
4285 txq->wqe_ci += wqe_n;
4286 loc->wqe_free -= wqe_n;
4288 * Packet data are completely inlined,
4289 * free the packet immediately.
4291 rte_pktmbuf_free_seg(loc->mbuf);
4292 } else if (!MLX5_TXOFF_CONFIG(EMPW) &&
4295 * If minimal inlining is requested the eMPW
4296 * feature should be disabled due to data is
4297 * inlined into Ethernet Segment, which can
4298 * not contain inlined data for eMPW due to
4299 * segment shared for all packets.
4301 struct mlx5_wqe_dseg *restrict dseg;
4306 * The inline-mode settings require
4307 * to inline the specified amount of
4308 * data bytes to the Ethernet Segment.
4309 * We should check the free space in
4310 * WQE ring buffer to inline partially.
4312 assert(txq->inlen_send >= txq->inlen_mode);
4313 assert(inlen > txq->inlen_mode);
4314 assert(txq->inlen_mode >=
4315 MLX5_ESEG_MIN_INLINE_SIZE);
4317 * Check whether there are enough free WQEBBs:
4319 * - Ethernet Segment
4320 * - First Segment of inlined Ethernet data
4321 * - ... data continued ...
4322 * - Finishing Data Segment of pointer type
4324 ds = (MLX5_WQE_CSEG_SIZE +
4325 MLX5_WQE_ESEG_SIZE +
4326 MLX5_WQE_DSEG_SIZE +
4328 MLX5_ESEG_MIN_INLINE_SIZE +
4329 MLX5_WQE_DSEG_SIZE +
4330 MLX5_WSEG_SIZE - 1) / MLX5_WSEG_SIZE;
4331 if (loc->wqe_free < ((ds + 3) / 4))
4332 return MLX5_TXCMP_CODE_EXIT;
4334 * Build the ordinary SEND WQE:
4336 * - Ethernet Segment, inline inlen_mode bytes
4337 * - Data Segment of pointer type
4339 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
4340 loc->wqe_last = wqe;
4341 mlx5_tx_cseg_init(txq, loc, wqe, ds,
4342 MLX5_OPCODE_SEND, olx);
4343 dseg = mlx5_tx_eseg_data(txq, loc, wqe, vlan,
4346 dptr = rte_pktmbuf_mtod(loc->mbuf, uint8_t *) +
4347 txq->inlen_mode - vlan;
4348 inlen -= txq->inlen_mode;
4349 mlx5_tx_dseg_ptr(txq, loc, dseg,
4352 * WQE is built, update the loop parameters
4353 * and got to the next packet.
4355 txq->wqe_ci += (ds + 3) / 4;
4356 loc->wqe_free -= (ds + 3) / 4;
4357 /* We have to store mbuf in elts.*/
4358 assert(MLX5_TXOFF_CONFIG(INLINE));
4359 txq->elts[txq->elts_head++ & txq->elts_m] =
4367 * Partially inlined packet data WQE, we have
4368 * some space in title WQEBB, we can fill it
4369 * with some packet data. It takes one WQEBB,
4370 * it is available, no extra space check:
4371 * - Control Segment, SEND opcode
4372 * - Ethernet Segment, no VLAN insertion
4373 * - MLX5_ESEG_MIN_INLINE_SIZE bytes of Data
4374 * - Data Segment, pointer type
4376 * We also get here if VLAN insertion is not
4377 * supported by HW, the inline is enabled.
4379 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
4380 loc->wqe_last = wqe;
4381 mlx5_tx_cseg_init(txq, loc, wqe, 4,
4382 MLX5_OPCODE_SEND, olx);
4383 mlx5_tx_eseg_dmin(txq, loc, wqe, vlan, olx);
4384 dptr = rte_pktmbuf_mtod(loc->mbuf, uint8_t *) +
4385 MLX5_ESEG_MIN_INLINE_SIZE - vlan;
4387 * The length check is performed above, by
4388 * comparing with txq->inlen_send. We should
4389 * not get overflow here.
4391 assert(inlen > MLX5_ESEG_MIN_INLINE_SIZE);
4392 dlen = inlen - MLX5_ESEG_MIN_INLINE_SIZE;
4393 mlx5_tx_dseg_ptr(txq, loc, &wqe->dseg[1],
4397 /* We have to store mbuf in elts.*/
4398 assert(MLX5_TXOFF_CONFIG(INLINE));
4399 txq->elts[txq->elts_head++ & txq->elts_m] =
4403 #ifdef MLX5_PMD_SOFT_COUNTERS
4404 /* Update sent data bytes counter. */
4405 txq->stats.obytes += vlan +
4406 rte_pktmbuf_data_len(loc->mbuf);
4410 * No inline at all, it means the CPU cycles saving
4411 * is prioritized at configuration, we should not
4412 * copy any packet data to WQE.
4414 * SEND WQE, one WQEBB:
4415 * - Control Segment, SEND opcode
4416 * - Ethernet Segment, optional VLAN, no inline
4417 * - Data Segment, pointer type
4419 wqe = txq->wqes + (txq->wqe_ci & txq->wqe_m);
4420 loc->wqe_last = wqe;
4421 mlx5_tx_cseg_init(txq, loc, wqe, 3,
4422 MLX5_OPCODE_SEND, olx);
4423 mlx5_tx_eseg_none(txq, loc, wqe, olx);
4425 (txq, loc, &wqe->dseg[0],
4426 rte_pktmbuf_mtod(loc->mbuf, uint8_t *),
4427 rte_pktmbuf_data_len(loc->mbuf), olx);
4431 * We should not store mbuf pointer in elts
4432 * if no inlining is configured, this is done
4433 * by calling routine in a batch copy.
4435 assert(!MLX5_TXOFF_CONFIG(INLINE));
4437 #ifdef MLX5_PMD_SOFT_COUNTERS
4438 /* Update sent data bytes counter. */
4439 txq->stats.obytes += rte_pktmbuf_data_len(loc->mbuf);
4440 if (MLX5_TXOFF_CONFIG(VLAN) &&
4441 loc->mbuf->ol_flags & PKT_TX_VLAN_PKT)
4442 txq->stats.obytes +=
4443 sizeof(struct rte_vlan_hdr);
4448 /* Request CQE generation if limits are reached. */
4449 mlx5_tx_request_completion(txq, loc, false, olx);
4450 if (unlikely(!pkts_n || !loc->elts_free || !loc->wqe_free))
4451 return MLX5_TXCMP_CODE_EXIT;
4452 loc->mbuf = *pkts++;
4454 rte_prefetch0(*pkts);
4455 ret = mlx5_tx_able_to_empw(txq, loc, olx, true);
4456 if (unlikely(ret != MLX5_TXCMP_CODE_SINGLE))
4462 static __rte_always_inline enum mlx5_txcmp_code
4463 mlx5_tx_burst_single(struct mlx5_txq_data *restrict txq,
4464 struct rte_mbuf **restrict pkts,
4465 unsigned int pkts_n,
4466 struct mlx5_txq_local *restrict loc,
4469 enum mlx5_txcmp_code ret;
4471 ret = mlx5_tx_able_to_empw(txq, loc, olx, false);
4472 if (ret == MLX5_TXCMP_CODE_SINGLE)
4474 assert(ret == MLX5_TXCMP_CODE_EMPW);
4476 /* Optimize for inline/no inline eMPW send. */
4477 ret = (MLX5_TXOFF_CONFIG(INLINE)) ?
4478 mlx5_tx_burst_empw_inline
4479 (txq, pkts, pkts_n, loc, olx) :
4480 mlx5_tx_burst_empw_simple
4481 (txq, pkts, pkts_n, loc, olx);
4482 if (ret != MLX5_TXCMP_CODE_SINGLE)
4484 /* The resources to send one packet should remain. */
4485 assert(loc->elts_free && loc->wqe_free);
4487 ret = mlx5_tx_burst_single_send(txq, pkts, pkts_n, loc, olx);
4488 assert(ret != MLX5_TXCMP_CODE_SINGLE);
4489 if (ret != MLX5_TXCMP_CODE_EMPW)
4491 /* The resources to send one packet should remain. */
4492 assert(loc->elts_free && loc->wqe_free);
4497 * DPDK Tx callback template. This is configured template
4498 * used to generate routines optimized for specified offload setup.
4499 * One of this generated functions is chosen at SQ configuration
4503 * Generic pointer to TX queue structure.
4505 * Packets to transmit.
4507 * Number of packets in array.
4509 * Configured offloads mask, presents the bits of MLX5_TXOFF_CONFIG_xxx
4510 * values. Should be static to take compile time static configuration
4514 * Number of packets successfully transmitted (<= pkts_n).
4516 static __rte_always_inline uint16_t
4517 mlx5_tx_burst_tmpl(struct mlx5_txq_data *restrict txq,
4518 struct rte_mbuf **restrict pkts,
4522 struct mlx5_txq_local loc;
4523 enum mlx5_txcmp_code ret;
4526 assert(txq->elts_s >= (uint16_t)(txq->elts_head - txq->elts_tail));
4527 assert(txq->wqe_s >= (uint16_t)(txq->wqe_ci - txq->wqe_pi));
4528 if (unlikely(!pkts_n))
4532 loc.wqe_last = NULL;
4535 loc.pkts_loop = loc.pkts_sent;
4537 * Check if there are some CQEs, if any:
4538 * - process an encountered errors
4539 * - process the completed WQEs
4540 * - free related mbufs
4541 * - doorbell the NIC about processed CQEs
4543 rte_prefetch0(*(pkts + loc.pkts_sent));
4544 mlx5_tx_handle_completion(txq, olx);
4546 * Calculate the number of available resources - elts and WQEs.
4547 * There are two possible different scenarios:
4548 * - no data inlining into WQEs, one WQEBB may contains upto
4549 * four packets, in this case elts become scarce resource
4550 * - data inlining into WQEs, one packet may require multiple
4551 * WQEBBs, the WQEs become the limiting factor.
4553 assert(txq->elts_s >= (uint16_t)(txq->elts_head - txq->elts_tail));
4554 loc.elts_free = txq->elts_s -
4555 (uint16_t)(txq->elts_head - txq->elts_tail);
4556 assert(txq->wqe_s >= (uint16_t)(txq->wqe_ci - txq->wqe_pi));
4557 loc.wqe_free = txq->wqe_s -
4558 (uint16_t)(txq->wqe_ci - txq->wqe_pi);
4559 if (unlikely(!loc.elts_free || !loc.wqe_free))
4560 return loc.pkts_sent;
4563 * Fetch the packet from array. Usually this is
4564 * the first packet in series of multi/single
4567 loc.mbuf = *(pkts + loc.pkts_sent);
4568 /* Dedicated branch for multi-segment packets. */
4569 if (MLX5_TXOFF_CONFIG(MULTI) &&
4570 unlikely(NB_SEGS(loc.mbuf) > 1)) {
4572 * Multi-segment packet encountered.
4573 * Hardware is able to process it only
4574 * with SEND/TSO opcodes, one packet
4575 * per WQE, do it in dedicated routine.
4578 assert(loc.pkts_sent >= loc.pkts_copy);
4579 part = loc.pkts_sent - loc.pkts_copy;
4580 if (!MLX5_TXOFF_CONFIG(INLINE) && part) {
4582 * There are some single-segment mbufs not
4583 * stored in elts. The mbufs must be in the
4584 * same order as WQEs, so we must copy the
4585 * mbufs to elts here, before the coming
4586 * multi-segment packet mbufs is appended.
4588 mlx5_tx_copy_elts(txq, pkts + loc.pkts_copy,
4590 loc.pkts_copy = loc.pkts_sent;
4592 assert(pkts_n > loc.pkts_sent);
4593 ret = mlx5_tx_burst_mseg(txq, pkts, pkts_n, &loc, olx);
4594 if (!MLX5_TXOFF_CONFIG(INLINE))
4595 loc.pkts_copy = loc.pkts_sent;
4597 * These returned code checks are supposed
4598 * to be optimized out due to routine inlining.
4600 if (ret == MLX5_TXCMP_CODE_EXIT) {
4602 * The routine returns this code when
4603 * all packets are sent or there is no
4604 * enough resources to complete request.
4608 if (ret == MLX5_TXCMP_CODE_ERROR) {
4610 * The routine returns this code when
4611 * some error in the incoming packets
4614 txq->stats.oerrors++;
4617 if (ret == MLX5_TXCMP_CODE_SINGLE) {
4619 * The single-segment packet was encountered
4620 * in the array, try to send it with the
4621 * best optimized way, possible engaging eMPW.
4623 goto enter_send_single;
4625 if (MLX5_TXOFF_CONFIG(TSO) &&
4626 ret == MLX5_TXCMP_CODE_TSO) {
4628 * The single-segment TSO packet was
4629 * encountered in the array.
4631 goto enter_send_tso;
4633 /* We must not get here. Something is going wrong. */
4635 txq->stats.oerrors++;
4638 /* Dedicated branch for single-segment TSO packets. */
4639 if (MLX5_TXOFF_CONFIG(TSO) &&
4640 unlikely(loc.mbuf->ol_flags & PKT_TX_TCP_SEG)) {
4642 * TSO might require special way for inlining
4643 * (dedicated parameters) and is sent with
4644 * MLX5_OPCODE_TSO opcode only, provide this
4645 * in dedicated branch.
4648 assert(NB_SEGS(loc.mbuf) == 1);
4649 assert(pkts_n > loc.pkts_sent);
4650 ret = mlx5_tx_burst_tso(txq, pkts, pkts_n, &loc, olx);
4652 * These returned code checks are supposed
4653 * to be optimized out due to routine inlining.
4655 if (ret == MLX5_TXCMP_CODE_EXIT)
4657 if (ret == MLX5_TXCMP_CODE_ERROR) {
4658 txq->stats.oerrors++;
4661 if (ret == MLX5_TXCMP_CODE_SINGLE)
4662 goto enter_send_single;
4663 if (MLX5_TXOFF_CONFIG(MULTI) &&
4664 ret == MLX5_TXCMP_CODE_MULTI) {
4666 * The multi-segment packet was
4667 * encountered in the array.
4669 goto enter_send_multi;
4671 /* We must not get here. Something is going wrong. */
4673 txq->stats.oerrors++;
4677 * The dedicated branch for the single-segment packets
4678 * without TSO. Often these ones can be sent using
4679 * MLX5_OPCODE_EMPW with multiple packets in one WQE.
4680 * The routine builds the WQEs till it encounters
4681 * the TSO or multi-segment packet (in case if these
4682 * offloads are requested at SQ configuration time).
4685 assert(pkts_n > loc.pkts_sent);
4686 ret = mlx5_tx_burst_single(txq, pkts, pkts_n, &loc, olx);
4688 * These returned code checks are supposed
4689 * to be optimized out due to routine inlining.
4691 if (ret == MLX5_TXCMP_CODE_EXIT)
4693 if (ret == MLX5_TXCMP_CODE_ERROR) {
4694 txq->stats.oerrors++;
4697 if (MLX5_TXOFF_CONFIG(MULTI) &&
4698 ret == MLX5_TXCMP_CODE_MULTI) {
4700 * The multi-segment packet was
4701 * encountered in the array.
4703 goto enter_send_multi;
4705 if (MLX5_TXOFF_CONFIG(TSO) &&
4706 ret == MLX5_TXCMP_CODE_TSO) {
4708 * The single-segment TSO packet was
4709 * encountered in the array.
4711 goto enter_send_tso;
4713 /* We must not get here. Something is going wrong. */
4715 txq->stats.oerrors++;
4719 * Main Tx loop is completed, do the rest:
4720 * - set completion request if thresholds are reached
4721 * - doorbell the hardware
4722 * - copy the rest of mbufs to elts (if any)
4724 assert(MLX5_TXOFF_CONFIG(INLINE) || loc.pkts_sent >= loc.pkts_copy);
4725 /* Take a shortcut if nothing is sent. */
4726 if (unlikely(loc.pkts_sent == loc.pkts_loop))
4727 return loc.pkts_sent;
4729 * Ring QP doorbell immediately after WQE building completion
4730 * to improve latencies. The pure software related data treatment
4731 * can be completed after doorbell. Tx CQEs for this SQ are
4732 * processed in this thread only by the polling.
4734 mlx5_tx_dbrec_cond_wmb(txq, loc.wqe_last, 0);
4735 /* Not all of the mbufs may be stored into elts yet. */
4736 part = MLX5_TXOFF_CONFIG(INLINE) ? 0 : loc.pkts_sent - loc.pkts_copy;
4737 if (!MLX5_TXOFF_CONFIG(INLINE) && part) {
4739 * There are some single-segment mbufs not stored in elts.
4740 * It can be only if the last packet was single-segment.
4741 * The copying is gathered into one place due to it is
4742 * a good opportunity to optimize that with SIMD.
4743 * Unfortunately if inlining is enabled the gaps in
4744 * pointer array may happen due to early freeing of the
4747 mlx5_tx_copy_elts(txq, pkts + loc.pkts_copy, part, olx);
4748 loc.pkts_copy = loc.pkts_sent;
4750 #ifdef MLX5_PMD_SOFT_COUNTERS
4751 /* Increment sent packets counter. */
4752 txq->stats.opackets += loc.pkts_sent;
4754 assert(txq->elts_s >= (uint16_t)(txq->elts_head - txq->elts_tail));
4755 assert(txq->wqe_s >= (uint16_t)(txq->wqe_ci - txq->wqe_pi));
4756 if (pkts_n > loc.pkts_sent) {
4758 * If burst size is large there might be no enough CQE
4759 * fetched from completion queue and no enough resources
4760 * freed to send all the packets.
4764 return loc.pkts_sent;
4767 /* Generate routines with Enhanced Multi-Packet Write support. */
4768 MLX5_TXOFF_DECL(full_empw,
4769 MLX5_TXOFF_CONFIG_FULL | MLX5_TXOFF_CONFIG_EMPW)
4771 MLX5_TXOFF_DECL(none_empw,
4772 MLX5_TXOFF_CONFIG_NONE | MLX5_TXOFF_CONFIG_EMPW)
4774 MLX5_TXOFF_DECL(md_empw,
4775 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4777 MLX5_TXOFF_DECL(mt_empw,
4778 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4779 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4781 MLX5_TXOFF_DECL(mtsc_empw,
4782 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4783 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4784 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4786 MLX5_TXOFF_DECL(mti_empw,
4787 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4788 MLX5_TXOFF_CONFIG_INLINE |
4789 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4791 MLX5_TXOFF_DECL(mtv_empw,
4792 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4793 MLX5_TXOFF_CONFIG_VLAN |
4794 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4796 MLX5_TXOFF_DECL(mtiv_empw,
4797 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4798 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4799 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4801 MLX5_TXOFF_DECL(sc_empw,
4802 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4803 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4805 MLX5_TXOFF_DECL(sci_empw,
4806 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4807 MLX5_TXOFF_CONFIG_INLINE |
4808 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4810 MLX5_TXOFF_DECL(scv_empw,
4811 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4812 MLX5_TXOFF_CONFIG_VLAN |
4813 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4815 MLX5_TXOFF_DECL(sciv_empw,
4816 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4817 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4818 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4820 MLX5_TXOFF_DECL(i_empw,
4821 MLX5_TXOFF_CONFIG_INLINE |
4822 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4824 MLX5_TXOFF_DECL(v_empw,
4825 MLX5_TXOFF_CONFIG_VLAN |
4826 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4828 MLX5_TXOFF_DECL(iv_empw,
4829 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4830 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4832 /* Generate routines without Enhanced Multi-Packet Write support. */
4833 MLX5_TXOFF_DECL(full,
4834 MLX5_TXOFF_CONFIG_FULL)
4836 MLX5_TXOFF_DECL(none,
4837 MLX5_TXOFF_CONFIG_NONE)
4840 MLX5_TXOFF_CONFIG_METADATA)
4843 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4844 MLX5_TXOFF_CONFIG_METADATA)
4846 MLX5_TXOFF_DECL(mtsc,
4847 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4848 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4849 MLX5_TXOFF_CONFIG_METADATA)
4851 MLX5_TXOFF_DECL(mti,
4852 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4853 MLX5_TXOFF_CONFIG_INLINE |
4854 MLX5_TXOFF_CONFIG_METADATA)
4857 MLX5_TXOFF_DECL(mtv,
4858 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4859 MLX5_TXOFF_CONFIG_VLAN |
4860 MLX5_TXOFF_CONFIG_METADATA)
4863 MLX5_TXOFF_DECL(mtiv,
4864 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4865 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4866 MLX5_TXOFF_CONFIG_METADATA)
4869 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4870 MLX5_TXOFF_CONFIG_METADATA)
4872 MLX5_TXOFF_DECL(sci,
4873 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4874 MLX5_TXOFF_CONFIG_INLINE |
4875 MLX5_TXOFF_CONFIG_METADATA)
4878 MLX5_TXOFF_DECL(scv,
4879 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4880 MLX5_TXOFF_CONFIG_VLAN |
4881 MLX5_TXOFF_CONFIG_METADATA)
4884 MLX5_TXOFF_DECL(sciv,
4885 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4886 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4887 MLX5_TXOFF_CONFIG_METADATA)
4890 MLX5_TXOFF_CONFIG_INLINE |
4891 MLX5_TXOFF_CONFIG_METADATA)
4894 MLX5_TXOFF_CONFIG_VLAN |
4895 MLX5_TXOFF_CONFIG_METADATA)
4898 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4899 MLX5_TXOFF_CONFIG_METADATA)
4902 * Array of declared and compiled Tx burst function and corresponding
4903 * supported offloads set. The array is used to select the Tx burst
4904 * function for specified offloads set at Tx queue configuration time.
4907 eth_tx_burst_t func;
4910 MLX5_TXOFF_INFO(full_empw,
4911 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4912 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4913 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4914 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4916 MLX5_TXOFF_INFO(none_empw,
4917 MLX5_TXOFF_CONFIG_NONE | MLX5_TXOFF_CONFIG_EMPW)
4919 MLX5_TXOFF_INFO(md_empw,
4920 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4922 MLX5_TXOFF_INFO(mt_empw,
4923 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4924 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4926 MLX5_TXOFF_INFO(mtsc_empw,
4927 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4928 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4929 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4931 MLX5_TXOFF_INFO(mti_empw,
4932 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4933 MLX5_TXOFF_CONFIG_INLINE |
4934 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4936 MLX5_TXOFF_INFO(mtv_empw,
4937 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4938 MLX5_TXOFF_CONFIG_VLAN |
4939 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4941 MLX5_TXOFF_INFO(mtiv_empw,
4942 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4943 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4944 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4946 MLX5_TXOFF_INFO(sc_empw,
4947 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4948 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4950 MLX5_TXOFF_INFO(sci_empw,
4951 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4952 MLX5_TXOFF_CONFIG_INLINE |
4953 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4955 MLX5_TXOFF_INFO(scv_empw,
4956 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4957 MLX5_TXOFF_CONFIG_VLAN |
4958 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4960 MLX5_TXOFF_INFO(sciv_empw,
4961 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4962 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4963 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4965 MLX5_TXOFF_INFO(i_empw,
4966 MLX5_TXOFF_CONFIG_INLINE |
4967 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4969 MLX5_TXOFF_INFO(v_empw,
4970 MLX5_TXOFF_CONFIG_VLAN |
4971 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4973 MLX5_TXOFF_INFO(iv_empw,
4974 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4975 MLX5_TXOFF_CONFIG_METADATA | MLX5_TXOFF_CONFIG_EMPW)
4977 MLX5_TXOFF_INFO(full,
4978 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4979 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4980 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
4981 MLX5_TXOFF_CONFIG_METADATA)
4983 MLX5_TXOFF_INFO(none,
4984 MLX5_TXOFF_CONFIG_NONE)
4987 MLX5_TXOFF_CONFIG_METADATA)
4990 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4991 MLX5_TXOFF_CONFIG_METADATA)
4993 MLX5_TXOFF_INFO(mtsc,
4994 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
4995 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
4996 MLX5_TXOFF_CONFIG_METADATA)
4998 MLX5_TXOFF_INFO(mti,
4999 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
5000 MLX5_TXOFF_CONFIG_INLINE |
5001 MLX5_TXOFF_CONFIG_METADATA)
5004 MLX5_TXOFF_INFO(mtv,
5005 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
5006 MLX5_TXOFF_CONFIG_VLAN |
5007 MLX5_TXOFF_CONFIG_METADATA)
5009 MLX5_TXOFF_INFO(mtiv,
5010 MLX5_TXOFF_CONFIG_MULTI | MLX5_TXOFF_CONFIG_TSO |
5011 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
5012 MLX5_TXOFF_CONFIG_METADATA)
5015 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
5016 MLX5_TXOFF_CONFIG_METADATA)
5018 MLX5_TXOFF_INFO(sci,
5019 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
5020 MLX5_TXOFF_CONFIG_INLINE |
5021 MLX5_TXOFF_CONFIG_METADATA)
5023 MLX5_TXOFF_INFO(scv,
5024 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
5025 MLX5_TXOFF_CONFIG_VLAN |
5026 MLX5_TXOFF_CONFIG_METADATA)
5028 MLX5_TXOFF_INFO(sciv,
5029 MLX5_TXOFF_CONFIG_SWP | MLX5_TXOFF_CONFIG_CSUM |
5030 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
5031 MLX5_TXOFF_CONFIG_METADATA)
5034 MLX5_TXOFF_CONFIG_INLINE |
5035 MLX5_TXOFF_CONFIG_METADATA)
5038 MLX5_TXOFF_CONFIG_VLAN |
5039 MLX5_TXOFF_CONFIG_METADATA)
5042 MLX5_TXOFF_CONFIG_INLINE | MLX5_TXOFF_CONFIG_VLAN |
5043 MLX5_TXOFF_CONFIG_METADATA)
5047 * Configure the Tx function to use. The routine checks configured
5048 * Tx offloads for the device and selects appropriate Tx burst
5049 * routine. There are multiple Tx burst routines compiled from
5050 * the same template in the most optimal way for the dedicated
5054 * Pointer to private data structure.
5057 * Pointer to selected Tx burst function.
5060 mlx5_select_tx_function(struct rte_eth_dev *dev)
5062 struct mlx5_priv *priv = dev->data->dev_private;
5063 struct mlx5_dev_config *config = &priv->config;
5064 uint64_t tx_offloads = dev->data->dev_conf.txmode.offloads;
5065 unsigned int diff = 0, olx = 0, i, m;
5067 static_assert(MLX5_WQE_SIZE_MAX / MLX5_WSEG_SIZE <=
5068 MLX5_DSEG_MAX, "invalid WQE max size");
5069 static_assert(MLX5_WQE_CSEG_SIZE == MLX5_WSEG_SIZE,
5070 "invalid WQE Control Segment size");
5071 static_assert(MLX5_WQE_ESEG_SIZE == MLX5_WSEG_SIZE,
5072 "invalid WQE Ethernet Segment size");
5073 static_assert(MLX5_WQE_DSEG_SIZE == MLX5_WSEG_SIZE,
5074 "invalid WQE Data Segment size");
5075 static_assert(MLX5_WQE_SIZE == 4 * MLX5_WSEG_SIZE,
5076 "invalid WQE size");
5078 if (tx_offloads & DEV_TX_OFFLOAD_MULTI_SEGS) {
5079 /* We should support Multi-Segment Packets. */
5080 olx |= MLX5_TXOFF_CONFIG_MULTI;
5082 if (tx_offloads & (DEV_TX_OFFLOAD_TCP_TSO |
5083 DEV_TX_OFFLOAD_VXLAN_TNL_TSO |
5084 DEV_TX_OFFLOAD_GRE_TNL_TSO |
5085 DEV_TX_OFFLOAD_IP_TNL_TSO |
5086 DEV_TX_OFFLOAD_UDP_TNL_TSO)) {
5087 /* We should support TCP Send Offload. */
5088 olx |= MLX5_TXOFF_CONFIG_TSO;
5090 if (tx_offloads & (DEV_TX_OFFLOAD_IP_TNL_TSO |
5091 DEV_TX_OFFLOAD_UDP_TNL_TSO |
5092 DEV_TX_OFFLOAD_OUTER_IPV4_CKSUM)) {
5093 /* We should support Software Parser for Tunnels. */
5094 olx |= MLX5_TXOFF_CONFIG_SWP;
5096 if (tx_offloads & (DEV_TX_OFFLOAD_IPV4_CKSUM |
5097 DEV_TX_OFFLOAD_UDP_CKSUM |
5098 DEV_TX_OFFLOAD_TCP_CKSUM |
5099 DEV_TX_OFFLOAD_OUTER_IPV4_CKSUM)) {
5100 /* We should support IP/TCP/UDP Checksums. */
5101 olx |= MLX5_TXOFF_CONFIG_CSUM;
5103 if (tx_offloads & DEV_TX_OFFLOAD_VLAN_INSERT) {
5104 /* We should support VLAN insertion. */
5105 olx |= MLX5_TXOFF_CONFIG_VLAN;
5107 if (priv->txqs_n && (*priv->txqs)[0]) {
5108 struct mlx5_txq_data *txd = (*priv->txqs)[0];
5110 if (txd->inlen_send) {
5112 * Check the data inline requirements. Data inline
5113 * is enabled on per device basis, we can check
5114 * the first Tx queue only.
5116 * If device does not support VLAN insertion in WQE
5117 * and some queues are requested to perform VLAN
5118 * insertion offload than inline must be enabled.
5120 olx |= MLX5_TXOFF_CONFIG_INLINE;
5123 if (config->mps == MLX5_MPW_ENHANCED &&
5124 config->txq_inline_min <= 0) {
5126 * The NIC supports Enhanced Multi-Packet Write.
5127 * We do not support legacy MPW due to its
5128 * hardware related problems, so we just ignore
5129 * legacy MLX5_MPW settings. There should be no
5130 * minimal required inline data.
5132 olx |= MLX5_TXOFF_CONFIG_EMPW;
5134 if (tx_offloads & DEV_TX_OFFLOAD_MATCH_METADATA) {
5135 /* We should support Flow metadata. */
5136 olx |= MLX5_TXOFF_CONFIG_METADATA;
5139 * Scan the routines table to find the minimal
5140 * satisfying routine with requested offloads.
5142 m = RTE_DIM(txoff_func);
5143 for (i = 0; i < RTE_DIM(txoff_func); i++) {
5146 tmp = txoff_func[i].olx;
5148 /* Meets requested offloads exactly.*/
5152 if ((tmp & olx) != olx) {
5153 /* Does not meet requested offloads at all. */
5156 if ((olx ^ tmp) & MLX5_TXOFF_CONFIG_EMPW)
5157 /* Do not enable eMPW if not configured. */
5159 if ((olx ^ tmp) & MLX5_TXOFF_CONFIG_INLINE)
5160 /* Do not enable inlining if not configured. */
5163 * Some routine meets the requirements.
5164 * Check whether it has minimal amount
5165 * of not requested offloads.
5167 tmp = __builtin_popcountl(tmp & ~olx);
5168 if (m >= RTE_DIM(txoff_func) || tmp < diff) {
5169 /* First or better match, save and continue. */
5175 tmp = txoff_func[i].olx ^ txoff_func[m].olx;
5176 if (__builtin_ffsl(txoff_func[i].olx & ~tmp) <
5177 __builtin_ffsl(txoff_func[m].olx & ~tmp)) {
5178 /* Lighter not requested offload. */
5183 if (m >= RTE_DIM(txoff_func)) {
5184 DRV_LOG(DEBUG, "port %u has no selected Tx function"
5185 " for requested offloads %04X",
5186 dev->data->port_id, olx);
5189 DRV_LOG(DEBUG, "port %u has selected Tx function"
5190 " supporting offloads %04X/%04X",
5191 dev->data->port_id, olx, txoff_func[m].olx);
5192 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_MULTI)
5193 DRV_LOG(DEBUG, "\tMULTI (multi segment)");
5194 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_TSO)
5195 DRV_LOG(DEBUG, "\tTSO (TCP send offload)");
5196 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_SWP)
5197 DRV_LOG(DEBUG, "\tSWP (software parser)");
5198 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_CSUM)
5199 DRV_LOG(DEBUG, "\tCSUM (checksum offload)");
5200 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_INLINE)
5201 DRV_LOG(DEBUG, "\tINLIN (inline data)");
5202 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_VLAN)
5203 DRV_LOG(DEBUG, "\tVLANI (VLAN insertion)");
5204 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_METADATA)
5205 DRV_LOG(DEBUG, "\tMETAD (tx Flow metadata)");
5206 if (txoff_func[m].olx & MLX5_TXOFF_CONFIG_EMPW)
5207 DRV_LOG(DEBUG, "\tEMPW (Enhanced MPW)");
5208 return txoff_func[m].func;