1 /* SPDX-License-Identifier: BSD-3-Clause
2 * Copyright(c) 2019 Intel Corporation
5 #include "ice_rxtx_vec_common.h"
9 #ifndef __INTEL_COMPILER
10 #pragma GCC diagnostic ignored "-Wcast-qual"
13 #define ICE_DESCS_PER_LOOP_AVX 8
16 ice_rxq_rearm(struct ice_rx_queue *rxq)
20 volatile union ice_rx_flex_desc *rxdp;
21 struct ice_rx_entry *rxep = &rxq->sw_ring[rxq->rxrearm_start];
22 struct rte_mempool_cache *cache = rte_mempool_default_cache(rxq->mp,
25 rxdp = rxq->rx_ring + rxq->rxrearm_start;
27 /* We need to pull 'n' more MBUFs into the software ring */
28 if (cache->len < ICE_RXQ_REARM_THRESH) {
29 uint32_t req = ICE_RXQ_REARM_THRESH + (cache->size -
32 int ret = rte_mempool_ops_dequeue_bulk(rxq->mp,
33 &cache->objs[cache->len], req);
37 if (rxq->rxrearm_nb + ICE_RXQ_REARM_THRESH >=
41 dma_addr0 = _mm_setzero_si128();
42 for (i = 0; i < ICE_DESCS_PER_LOOP; i++) {
43 rxep[i].mbuf = &rxq->fake_mbuf;
45 ((__m128i *)&rxdp[i].read,
49 rte_eth_devices[rxq->port_id].data->rx_mbuf_alloc_failed +=
55 const __m512i iova_offsets = _mm512_set1_epi64
56 (offsetof(struct rte_mbuf, buf_iova));
57 const __m512i headroom = _mm512_set1_epi64(RTE_PKTMBUF_HEADROOM);
59 #ifndef RTE_LIBRTE_ICE_16BYTE_RX_DESC
60 /* shuffle the iova into correct slots. Values 4-7 will contain
61 * zeros, so use 7 for a zero-value.
63 const __m512i permute_idx = _mm512_set_epi64(7, 7, 3, 1, 7, 7, 2, 0);
65 const __m512i permute_idx = _mm512_set_epi64(7, 3, 6, 2, 5, 1, 4, 0);
68 /* fill up the rxd in vector, process 8 mbufs in one loop */
69 for (i = 0; i < ICE_RXQ_REARM_THRESH / 8; i++) {
70 const __m512i mbuf_ptrs = _mm512_loadu_si512
71 (&cache->objs[cache->len - 8]);
72 _mm512_store_si512(rxep, mbuf_ptrs);
74 /* gather iova of mbuf0-7 into one zmm reg */
75 const __m512i iova_base_addrs = _mm512_i64gather_epi64
76 (_mm512_add_epi64(mbuf_ptrs, iova_offsets),
79 const __m512i iova_addrs = _mm512_add_epi64(iova_base_addrs,
81 #ifndef RTE_LIBRTE_ICE_16BYTE_RX_DESC
82 const __m512i iovas0 = _mm512_castsi256_si512
83 (_mm512_extracti64x4_epi64(iova_addrs, 0));
84 const __m512i iovas1 = _mm512_castsi256_si512
85 (_mm512_extracti64x4_epi64(iova_addrs, 1));
87 /* permute leaves iova 2-3 in hdr_addr of desc 0-1
88 * but these are ignored by driver since header split not
89 * enabled. Similarly for desc 4 & 5.
91 const __m512i desc0_1 = _mm512_permutexvar_epi64
92 (permute_idx, iovas0);
93 const __m512i desc2_3 = _mm512_bsrli_epi128(desc0_1, 8);
95 const __m512i desc4_5 = _mm512_permutexvar_epi64
96 (permute_idx, iovas1);
97 const __m512i desc6_7 = _mm512_bsrli_epi128(desc4_5, 8);
99 _mm512_store_si512((void *)rxdp, desc0_1);
100 _mm512_store_si512((void *)(rxdp + 2), desc2_3);
101 _mm512_store_si512((void *)(rxdp + 4), desc4_5);
102 _mm512_store_si512((void *)(rxdp + 6), desc6_7);
104 /* permute leaves iova 4-7 in hdr_addr of desc 0-3
105 * but these are ignored by driver since header split not
108 const __m512i desc0_3 = _mm512_permutexvar_epi64
109 (permute_idx, iova_addrs);
110 const __m512i desc4_7 = _mm512_bsrli_epi128(desc0_3, 8);
112 _mm512_store_si512((void *)rxdp, desc0_3);
113 _mm512_store_si512((void *)(rxdp + 4), desc4_7);
115 rxep += 8, rxdp += 8, cache->len -= 8;
118 rxq->rxrearm_start += ICE_RXQ_REARM_THRESH;
119 if (rxq->rxrearm_start >= rxq->nb_rx_desc)
120 rxq->rxrearm_start = 0;
122 rxq->rxrearm_nb -= ICE_RXQ_REARM_THRESH;
124 rx_id = (uint16_t)((rxq->rxrearm_start == 0) ?
125 (rxq->nb_rx_desc - 1) : (rxq->rxrearm_start - 1));
127 /* Update the tail pointer on the NIC */
128 ICE_PCI_REG_WRITE(rxq->qrx_tail, rx_id);
131 static inline __m256i
132 ice_flex_rxd_to_fdir_flags_vec_avx512(const __m256i fdir_id0_7)
134 #define FDID_MIS_MAGIC 0xFFFFFFFF
135 RTE_BUILD_BUG_ON(PKT_RX_FDIR != (1 << 2));
136 RTE_BUILD_BUG_ON(PKT_RX_FDIR_ID != (1 << 13));
137 const __m256i pkt_fdir_bit = _mm256_set1_epi32(PKT_RX_FDIR |
139 /* desc->flow_id field == 0xFFFFFFFF means fdir mismatch */
140 const __m256i fdir_mis_mask = _mm256_set1_epi32(FDID_MIS_MAGIC);
141 __m256i fdir_mask = _mm256_cmpeq_epi32(fdir_id0_7,
143 /* this XOR op results to bit-reverse the fdir_mask */
144 fdir_mask = _mm256_xor_si256(fdir_mask, fdir_mis_mask);
145 const __m256i fdir_flags = _mm256_and_si256(fdir_mask, pkt_fdir_bit);
150 static inline uint16_t
151 _ice_recv_raw_pkts_vec_avx512(struct ice_rx_queue *rxq,
152 struct rte_mbuf **rx_pkts,
153 uint16_t nb_pkts, uint8_t *split_packet)
155 const uint32_t *ptype_tbl = rxq->vsi->adapter->ptype_tbl;
156 const __m256i mbuf_init = _mm256_set_epi64x(0, 0,
157 0, rxq->mbuf_initializer);
158 struct ice_rx_entry *sw_ring = &rxq->sw_ring[rxq->rx_tail];
159 volatile union ice_rx_flex_desc *rxdp = rxq->rx_ring + rxq->rx_tail;
163 /* nb_pkts has to be floor-aligned to ICE_DESCS_PER_LOOP_AVX */
164 nb_pkts = RTE_ALIGN_FLOOR(nb_pkts, ICE_DESCS_PER_LOOP_AVX);
166 /* See if we need to rearm the RX queue - gives the prefetch a bit
169 if (rxq->rxrearm_nb > ICE_RXQ_REARM_THRESH)
172 /* Before we start moving massive data around, check to see if
173 * there is actually a packet available
175 if (!(rxdp->wb.status_error0 &
176 rte_cpu_to_le_32(1 << ICE_RX_FLEX_DESC_STATUS0_DD_S)))
179 /* constants used in processing loop */
180 const __m512i crc_adjust =
182 (0, /* ignore non-length fields */
183 -rxq->crc_len, /* sub crc on data_len */
184 -rxq->crc_len, /* sub crc on pkt_len */
185 0 /* ignore non-length fields */
188 /* 8 packets DD mask, LSB in each 32-bit value */
189 const __m256i dd_check = _mm256_set1_epi32(1);
191 /* 8 packets EOP mask, second-LSB in each 32-bit value */
192 const __m256i eop_check = _mm256_slli_epi32(dd_check,
193 ICE_RX_DESC_STATUS_EOF_S);
195 /* mask to shuffle from desc. to mbuf (4 descriptors)*/
196 const __m512i shuf_msk =
198 (/* rss hash parsed separately */
200 /* octet 10~11, 16 bits vlan_macip */
201 /* octet 4~5, 16 bits data_len */
202 11 << 24 | 10 << 16 | 5 << 8 | 4,
203 /* skip hi 16 bits pkt_len, zero out */
204 /* octet 4~5, 16 bits pkt_len */
205 0xFFFF << 16 | 5 << 8 | 4,
206 /* pkt_type set as unknown */
211 * compile-time check the above crc and shuffle layout is correct.
212 * NOTE: the first field (lowest address) is given last in set_epi
215 RTE_BUILD_BUG_ON(offsetof(struct rte_mbuf, pkt_len) !=
216 offsetof(struct rte_mbuf, rx_descriptor_fields1) + 4);
217 RTE_BUILD_BUG_ON(offsetof(struct rte_mbuf, data_len) !=
218 offsetof(struct rte_mbuf, rx_descriptor_fields1) + 8);
219 RTE_BUILD_BUG_ON(offsetof(struct rte_mbuf, vlan_tci) !=
220 offsetof(struct rte_mbuf, rx_descriptor_fields1) + 10);
221 RTE_BUILD_BUG_ON(offsetof(struct rte_mbuf, hash) !=
222 offsetof(struct rte_mbuf, rx_descriptor_fields1) + 12);
224 /* Status/Error flag masks */
226 * mask everything except Checksum Reports, RSS indication
227 * and VLAN indication.
228 * bit6:4 for IP/L4 checksum errors.
229 * bit12 is for RSS indication.
230 * bit13 is for VLAN indication.
232 const __m256i flags_mask =
233 _mm256_set1_epi32((0xF << 4) | (1 << 12) | (1 << 13));
235 * data to be shuffled by the result of the flags mask shifted by 4
236 * bits. This gives use the l3_l4 flags.
238 const __m256i l3_l4_flags_shuf =
239 _mm256_set_epi8((PKT_RX_OUTER_L4_CKSUM_BAD >> 20 |
240 PKT_RX_OUTER_IP_CKSUM_BAD | PKT_RX_L4_CKSUM_BAD |
241 PKT_RX_IP_CKSUM_BAD) >> 1,
242 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
243 PKT_RX_L4_CKSUM_BAD | PKT_RX_IP_CKSUM_GOOD) >> 1,
244 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
245 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_BAD) >> 1,
246 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
247 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_GOOD) >> 1,
248 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_BAD |
249 PKT_RX_IP_CKSUM_BAD) >> 1,
250 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_BAD |
251 PKT_RX_IP_CKSUM_GOOD) >> 1,
252 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_GOOD |
253 PKT_RX_IP_CKSUM_BAD) >> 1,
254 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_GOOD |
255 PKT_RX_IP_CKSUM_GOOD) >> 1,
256 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
257 PKT_RX_L4_CKSUM_BAD | PKT_RX_IP_CKSUM_BAD) >> 1,
258 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
259 PKT_RX_L4_CKSUM_BAD | PKT_RX_IP_CKSUM_GOOD) >> 1,
260 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
261 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_BAD) >> 1,
262 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
263 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_GOOD) >> 1,
264 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_BAD |
265 PKT_RX_IP_CKSUM_BAD) >> 1,
266 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_BAD |
267 PKT_RX_IP_CKSUM_GOOD) >> 1,
268 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_GOOD |
269 PKT_RX_IP_CKSUM_BAD) >> 1,
270 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_GOOD |
271 PKT_RX_IP_CKSUM_GOOD) >> 1,
274 * shift right 20 bits to use the low two bits to indicate
275 * outer checksum status
276 * shift right 1 bit to make sure it not exceed 255
278 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
279 PKT_RX_L4_CKSUM_BAD | PKT_RX_IP_CKSUM_BAD) >> 1,
280 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
281 PKT_RX_L4_CKSUM_BAD | PKT_RX_IP_CKSUM_GOOD) >> 1,
282 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
283 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_BAD) >> 1,
284 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
285 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_GOOD) >> 1,
286 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_BAD |
287 PKT_RX_IP_CKSUM_BAD) >> 1,
288 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_BAD |
289 PKT_RX_IP_CKSUM_GOOD) >> 1,
290 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_GOOD |
291 PKT_RX_IP_CKSUM_BAD) >> 1,
292 (PKT_RX_OUTER_L4_CKSUM_BAD >> 20 | PKT_RX_L4_CKSUM_GOOD |
293 PKT_RX_IP_CKSUM_GOOD) >> 1,
294 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
295 PKT_RX_L4_CKSUM_BAD | PKT_RX_IP_CKSUM_BAD) >> 1,
296 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
297 PKT_RX_L4_CKSUM_BAD | PKT_RX_IP_CKSUM_GOOD) >> 1,
298 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
299 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_BAD) >> 1,
300 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_OUTER_IP_CKSUM_BAD |
301 PKT_RX_L4_CKSUM_GOOD | PKT_RX_IP_CKSUM_GOOD) >> 1,
302 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_BAD |
303 PKT_RX_IP_CKSUM_BAD) >> 1,
304 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_BAD |
305 PKT_RX_IP_CKSUM_GOOD) >> 1,
306 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_GOOD |
307 PKT_RX_IP_CKSUM_BAD) >> 1,
308 (PKT_RX_OUTER_L4_CKSUM_GOOD >> 20 | PKT_RX_L4_CKSUM_GOOD |
309 PKT_RX_IP_CKSUM_GOOD) >> 1);
310 const __m256i cksum_mask =
311 _mm256_set1_epi32(PKT_RX_IP_CKSUM_MASK |
312 PKT_RX_L4_CKSUM_MASK |
313 PKT_RX_OUTER_IP_CKSUM_BAD |
314 PKT_RX_OUTER_L4_CKSUM_MASK);
316 * data to be shuffled by result of flag mask, shifted down 12.
317 * If RSS(bit12)/VLAN(bit13) are set,
318 * shuffle moves appropriate flags in place.
320 const __m256i rss_vlan_flags_shuf = _mm256_set_epi8(0, 0, 0, 0,
323 PKT_RX_RSS_HASH | PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED,
324 PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED,
330 PKT_RX_RSS_HASH | PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED,
331 PKT_RX_VLAN | PKT_RX_VLAN_STRIPPED,
334 uint16_t i, received;
336 for (i = 0, received = 0; i < nb_pkts;
337 i += ICE_DESCS_PER_LOOP_AVX,
338 rxdp += ICE_DESCS_PER_LOOP_AVX) {
339 /* step 1, copy over 8 mbuf pointers to rx_pkts array */
340 _mm256_storeu_si256((void *)&rx_pkts[i],
341 _mm256_loadu_si256((void *)&sw_ring[i]));
342 #ifdef RTE_ARCH_X86_64
344 ((void *)&rx_pkts[i + 4],
345 _mm256_loadu_si256((void *)&sw_ring[i + 4]));
348 __m512i raw_desc0_3, raw_desc4_7;
349 __m256i raw_desc0_1, raw_desc2_3, raw_desc4_5, raw_desc6_7;
351 /* load in descriptors, in reverse order */
352 const __m128i raw_desc7 =
353 _mm_load_si128((void *)(rxdp + 7));
354 rte_compiler_barrier();
355 const __m128i raw_desc6 =
356 _mm_load_si128((void *)(rxdp + 6));
357 rte_compiler_barrier();
358 const __m128i raw_desc5 =
359 _mm_load_si128((void *)(rxdp + 5));
360 rte_compiler_barrier();
361 const __m128i raw_desc4 =
362 _mm_load_si128((void *)(rxdp + 4));
363 rte_compiler_barrier();
364 const __m128i raw_desc3 =
365 _mm_load_si128((void *)(rxdp + 3));
366 rte_compiler_barrier();
367 const __m128i raw_desc2 =
368 _mm_load_si128((void *)(rxdp + 2));
369 rte_compiler_barrier();
370 const __m128i raw_desc1 =
371 _mm_load_si128((void *)(rxdp + 1));
372 rte_compiler_barrier();
373 const __m128i raw_desc0 =
374 _mm_load_si128((void *)(rxdp + 0));
377 _mm256_inserti128_si256
378 (_mm256_castsi128_si256(raw_desc6),
381 _mm256_inserti128_si256
382 (_mm256_castsi128_si256(raw_desc4),
385 _mm256_inserti128_si256
386 (_mm256_castsi128_si256(raw_desc2),
389 _mm256_inserti128_si256
390 (_mm256_castsi128_si256(raw_desc0),
395 (_mm512_castsi256_si512(raw_desc4_5),
399 (_mm512_castsi256_si512(raw_desc0_1),
405 for (j = 0; j < ICE_DESCS_PER_LOOP_AVX; j++)
406 rte_mbuf_prefetch_part2(rx_pkts[i + j]);
410 * convert descriptors 0-7 into mbufs, re-arrange fields.
411 * Then write into the mbuf.
413 __m512i mb4_7 = _mm512_shuffle_epi8(raw_desc4_7, shuf_msk);
414 __m512i mb0_3 = _mm512_shuffle_epi8(raw_desc0_3, shuf_msk);
416 mb4_7 = _mm512_add_epi32(mb4_7, crc_adjust);
417 mb0_3 = _mm512_add_epi32(mb0_3, crc_adjust);
420 * to get packet types, ptype is located in bit16-25
423 const __m512i ptype_mask =
424 _mm512_set1_epi16(ICE_RX_FLEX_DESC_PTYPE_M);
427 * to get packet types, ptype is located in bit16-25
430 const __m512i ptypes4_7 =
431 _mm512_and_si512(raw_desc4_7, ptype_mask);
432 const __m512i ptypes0_3 =
433 _mm512_and_si512(raw_desc0_3, ptype_mask);
435 const __m256i ptypes6_7 =
436 _mm512_extracti64x4_epi64(ptypes4_7, 1);
437 const __m256i ptypes4_5 =
438 _mm512_extracti64x4_epi64(ptypes4_7, 0);
439 const __m256i ptypes2_3 =
440 _mm512_extracti64x4_epi64(ptypes0_3, 1);
441 const __m256i ptypes0_1 =
442 _mm512_extracti64x4_epi64(ptypes0_3, 0);
443 const uint16_t ptype7 = _mm256_extract_epi16(ptypes6_7, 9);
444 const uint16_t ptype6 = _mm256_extract_epi16(ptypes6_7, 1);
445 const uint16_t ptype5 = _mm256_extract_epi16(ptypes4_5, 9);
446 const uint16_t ptype4 = _mm256_extract_epi16(ptypes4_5, 1);
447 const uint16_t ptype3 = _mm256_extract_epi16(ptypes2_3, 9);
448 const uint16_t ptype2 = _mm256_extract_epi16(ptypes2_3, 1);
449 const uint16_t ptype1 = _mm256_extract_epi16(ptypes0_1, 9);
450 const uint16_t ptype0 = _mm256_extract_epi16(ptypes0_1, 1);
452 const __m512i ptype4_7 = _mm512_set_epi32
453 (0, 0, 0, ptype_tbl[ptype7],
454 0, 0, 0, ptype_tbl[ptype6],
455 0, 0, 0, ptype_tbl[ptype5],
456 0, 0, 0, ptype_tbl[ptype4]);
457 const __m512i ptype0_3 = _mm512_set_epi32
458 (0, 0, 0, ptype_tbl[ptype3],
459 0, 0, 0, ptype_tbl[ptype2],
460 0, 0, 0, ptype_tbl[ptype1],
461 0, 0, 0, ptype_tbl[ptype0]);
463 mb4_7 = _mm512_mask_blend_epi32(0x1111, mb4_7, ptype4_7);
464 mb0_3 = _mm512_mask_blend_epi32(0x1111, mb0_3, ptype0_3);
466 __m256i mb4_5 = _mm512_extracti64x4_epi64(mb4_7, 0);
467 __m256i mb6_7 = _mm512_extracti64x4_epi64(mb4_7, 1);
468 __m256i mb0_1 = _mm512_extracti64x4_epi64(mb0_3, 0);
469 __m256i mb2_3 = _mm512_extracti64x4_epi64(mb0_3, 1);
472 * use permute/extract to get status content
473 * After the operations, the packets status flags are in the
474 * order (hi->lo): [1, 3, 5, 7, 0, 2, 4, 6]
476 /* merge the status bits into one register */
477 const __m512i status_permute_msk = _mm512_set_epi32
482 const __m512i raw_status0_7 = _mm512_permutex2var_epi32
483 (raw_desc4_7, status_permute_msk, raw_desc0_3);
484 __m256i status0_7 = _mm512_extracti64x4_epi64
487 /* now do flag manipulation */
489 /* get only flag/error bits we want */
490 const __m256i flag_bits =
491 _mm256_and_si256(status0_7, flags_mask);
493 * l3_l4_error flags, shuffle, then shift to correct adjustment
494 * of flags in flags_shuf, and finally mask out extra bits
496 __m256i l3_l4_flags = _mm256_shuffle_epi8(l3_l4_flags_shuf,
497 _mm256_srli_epi32(flag_bits, 4));
498 l3_l4_flags = _mm256_slli_epi32(l3_l4_flags, 1);
499 __m256i l4_outer_mask = _mm256_set1_epi32(0x6);
500 __m256i l4_outer_flags =
501 _mm256_and_si256(l3_l4_flags, l4_outer_mask);
502 l4_outer_flags = _mm256_slli_epi32(l4_outer_flags, 20);
504 __m256i l3_l4_mask = _mm256_set1_epi32(~0x6);
505 l3_l4_flags = _mm256_and_si256(l3_l4_flags, l3_l4_mask);
506 l3_l4_flags = _mm256_or_si256(l3_l4_flags, l4_outer_flags);
507 l3_l4_flags = _mm256_and_si256(l3_l4_flags, cksum_mask);
508 /* set rss and vlan flags */
509 const __m256i rss_vlan_flag_bits =
510 _mm256_srli_epi32(flag_bits, 12);
511 const __m256i rss_vlan_flags =
512 _mm256_shuffle_epi8(rss_vlan_flags_shuf,
516 __m256i mbuf_flags = _mm256_or_si256(l3_l4_flags,
519 if (rxq->fdir_enabled) {
520 const __m256i fdir_id4_7 =
521 _mm256_unpackhi_epi32(raw_desc6_7, raw_desc4_5);
523 const __m256i fdir_id0_3 =
524 _mm256_unpackhi_epi32(raw_desc2_3, raw_desc0_1);
526 const __m256i fdir_id0_7 =
527 _mm256_unpackhi_epi64(fdir_id4_7, fdir_id0_3);
529 const __m256i fdir_flags =
530 ice_flex_rxd_to_fdir_flags_vec_avx512
533 /* merge with fdir_flags */
534 mbuf_flags = _mm256_or_si256(mbuf_flags, fdir_flags);
536 /* write to mbuf: have to use scalar store here */
537 rx_pkts[i + 0]->hash.fdir.hi =
538 _mm256_extract_epi32(fdir_id0_7, 3);
540 rx_pkts[i + 1]->hash.fdir.hi =
541 _mm256_extract_epi32(fdir_id0_7, 7);
543 rx_pkts[i + 2]->hash.fdir.hi =
544 _mm256_extract_epi32(fdir_id0_7, 2);
546 rx_pkts[i + 3]->hash.fdir.hi =
547 _mm256_extract_epi32(fdir_id0_7, 6);
549 rx_pkts[i + 4]->hash.fdir.hi =
550 _mm256_extract_epi32(fdir_id0_7, 1);
552 rx_pkts[i + 5]->hash.fdir.hi =
553 _mm256_extract_epi32(fdir_id0_7, 5);
555 rx_pkts[i + 6]->hash.fdir.hi =
556 _mm256_extract_epi32(fdir_id0_7, 0);
558 rx_pkts[i + 7]->hash.fdir.hi =
559 _mm256_extract_epi32(fdir_id0_7, 4);
560 } /* if() on fdir_enabled */
562 #ifndef RTE_LIBRTE_ICE_16BYTE_RX_DESC
564 * needs to load 2nd 16B of each desc for RSS hash parsing,
565 * will cause performance drop to get into this context.
567 if (rxq->vsi->adapter->eth_dev->data->dev_conf.rxmode.offloads &
568 DEV_RX_OFFLOAD_RSS_HASH) {
569 /* load bottom half of every 32B desc */
570 const __m128i raw_desc_bh7 =
572 ((void *)(&rxdp[7].wb.status_error1));
573 rte_compiler_barrier();
574 const __m128i raw_desc_bh6 =
576 ((void *)(&rxdp[6].wb.status_error1));
577 rte_compiler_barrier();
578 const __m128i raw_desc_bh5 =
580 ((void *)(&rxdp[5].wb.status_error1));
581 rte_compiler_barrier();
582 const __m128i raw_desc_bh4 =
584 ((void *)(&rxdp[4].wb.status_error1));
585 rte_compiler_barrier();
586 const __m128i raw_desc_bh3 =
588 ((void *)(&rxdp[3].wb.status_error1));
589 rte_compiler_barrier();
590 const __m128i raw_desc_bh2 =
592 ((void *)(&rxdp[2].wb.status_error1));
593 rte_compiler_barrier();
594 const __m128i raw_desc_bh1 =
596 ((void *)(&rxdp[1].wb.status_error1));
597 rte_compiler_barrier();
598 const __m128i raw_desc_bh0 =
600 ((void *)(&rxdp[0].wb.status_error1));
602 __m256i raw_desc_bh6_7 =
603 _mm256_inserti128_si256
604 (_mm256_castsi128_si256(raw_desc_bh6),
606 __m256i raw_desc_bh4_5 =
607 _mm256_inserti128_si256
608 (_mm256_castsi128_si256(raw_desc_bh4),
610 __m256i raw_desc_bh2_3 =
611 _mm256_inserti128_si256
612 (_mm256_castsi128_si256(raw_desc_bh2),
614 __m256i raw_desc_bh0_1 =
615 _mm256_inserti128_si256
616 (_mm256_castsi128_si256(raw_desc_bh0),
620 * to shift the 32b RSS hash value to the
621 * highest 32b of each 128b before mask
623 __m256i rss_hash6_7 =
624 _mm256_slli_epi64(raw_desc_bh6_7, 32);
625 __m256i rss_hash4_5 =
626 _mm256_slli_epi64(raw_desc_bh4_5, 32);
627 __m256i rss_hash2_3 =
628 _mm256_slli_epi64(raw_desc_bh2_3, 32);
629 __m256i rss_hash0_1 =
630 _mm256_slli_epi64(raw_desc_bh0_1, 32);
632 __m256i rss_hash_msk =
633 _mm256_set_epi32(0xFFFFFFFF, 0, 0, 0,
634 0xFFFFFFFF, 0, 0, 0);
636 rss_hash6_7 = _mm256_and_si256
637 (rss_hash6_7, rss_hash_msk);
638 rss_hash4_5 = _mm256_and_si256
639 (rss_hash4_5, rss_hash_msk);
640 rss_hash2_3 = _mm256_and_si256
641 (rss_hash2_3, rss_hash_msk);
642 rss_hash0_1 = _mm256_and_si256
643 (rss_hash0_1, rss_hash_msk);
645 mb6_7 = _mm256_or_si256(mb6_7, rss_hash6_7);
646 mb4_5 = _mm256_or_si256(mb4_5, rss_hash4_5);
647 mb2_3 = _mm256_or_si256(mb2_3, rss_hash2_3);
648 mb0_1 = _mm256_or_si256(mb0_1, rss_hash0_1);
649 } /* if() on RSS hash parsing */
653 * At this point, we have the 8 sets of flags in the low 16-bits
654 * of each 32-bit value in vlan0.
655 * We want to extract these, and merge them with the mbuf init
656 * data so we can do a single write to the mbuf to set the flags
657 * and all the other initialization fields. Extracting the
658 * appropriate flags means that we have to do a shift and blend
659 * for each mbuf before we do the write. However, we can also
660 * add in the previously computed rx_descriptor fields to
661 * make a single 256-bit write per mbuf
663 /* check the structure matches expectations */
664 RTE_BUILD_BUG_ON(offsetof(struct rte_mbuf, ol_flags) !=
665 offsetof(struct rte_mbuf, rearm_data) + 8);
666 RTE_BUILD_BUG_ON(offsetof(struct rte_mbuf, rearm_data) !=
667 RTE_ALIGN(offsetof(struct rte_mbuf,
670 /* build up data and do writes */
671 __m256i rearm0, rearm1, rearm2, rearm3, rearm4, rearm5,
674 rearm6 = _mm256_blend_epi32(mbuf_init,
675 _mm256_slli_si256(mbuf_flags, 8),
677 rearm4 = _mm256_blend_epi32(mbuf_init,
678 _mm256_slli_si256(mbuf_flags, 4),
680 rearm2 = _mm256_blend_epi32(mbuf_init, mbuf_flags, 0x04);
681 rearm0 = _mm256_blend_epi32(mbuf_init,
682 _mm256_srli_si256(mbuf_flags, 4),
685 /* permute to add in the rx_descriptor e.g. rss fields */
686 rearm6 = _mm256_permute2f128_si256(rearm6, mb6_7, 0x20);
687 rearm4 = _mm256_permute2f128_si256(rearm4, mb4_5, 0x20);
688 rearm2 = _mm256_permute2f128_si256(rearm2, mb2_3, 0x20);
689 rearm0 = _mm256_permute2f128_si256(rearm0, mb0_1, 0x20);
692 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 6]->rearm_data,
694 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 4]->rearm_data,
696 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 2]->rearm_data,
698 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 0]->rearm_data,
701 /* repeat for the odd mbufs */
702 const __m256i odd_flags =
703 _mm256_castsi128_si256
704 (_mm256_extracti128_si256(mbuf_flags, 1));
705 rearm7 = _mm256_blend_epi32(mbuf_init,
706 _mm256_slli_si256(odd_flags, 8),
708 rearm5 = _mm256_blend_epi32(mbuf_init,
709 _mm256_slli_si256(odd_flags, 4),
711 rearm3 = _mm256_blend_epi32(mbuf_init, odd_flags, 0x04);
712 rearm1 = _mm256_blend_epi32(mbuf_init,
713 _mm256_srli_si256(odd_flags, 4),
716 /* since odd mbufs are already in hi 128-bits use blend */
717 rearm7 = _mm256_blend_epi32(rearm7, mb6_7, 0xF0);
718 rearm5 = _mm256_blend_epi32(rearm5, mb4_5, 0xF0);
719 rearm3 = _mm256_blend_epi32(rearm3, mb2_3, 0xF0);
720 rearm1 = _mm256_blend_epi32(rearm1, mb0_1, 0xF0);
721 /* again write to mbufs */
722 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 7]->rearm_data,
724 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 5]->rearm_data,
726 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 3]->rearm_data,
728 _mm256_storeu_si256((__m256i *)&rx_pkts[i + 1]->rearm_data,
731 /* extract and record EOP bit */
733 const __m128i eop_mask =
734 _mm_set1_epi16(1 << ICE_RX_DESC_STATUS_EOF_S);
735 const __m256i eop_bits256 = _mm256_and_si256(status0_7,
737 /* pack status bits into a single 128-bit register */
738 const __m128i eop_bits =
740 (_mm256_castsi256_si128(eop_bits256),
741 _mm256_extractf128_si256(eop_bits256,
744 * flip bits, and mask out the EOP bit, which is now
745 * a split-packet bit i.e. !EOP, rather than EOP one.
747 __m128i split_bits = _mm_andnot_si128(eop_bits,
750 * eop bits are out of order, so we need to shuffle them
751 * back into order again. In doing so, only use low 8
752 * bits, which acts like another pack instruction
753 * The original order is (hi->lo): 1,3,5,7,0,2,4,6
754 * [Since we use epi8, the 16-bit positions are
755 * multiplied by 2 in the eop_shuffle value.]
757 __m128i eop_shuffle =
758 _mm_set_epi8(/* zero hi 64b */
759 0xFF, 0xFF, 0xFF, 0xFF,
760 0xFF, 0xFF, 0xFF, 0xFF,
761 /* move values to lo 64b */
764 split_bits = _mm_shuffle_epi8(split_bits, eop_shuffle);
765 *(uint64_t *)split_packet =
766 _mm_cvtsi128_si64(split_bits);
767 split_packet += ICE_DESCS_PER_LOOP_AVX;
770 /* perform dd_check */
771 status0_7 = _mm256_and_si256(status0_7, dd_check);
772 status0_7 = _mm256_packs_epi32(status0_7,
773 _mm256_setzero_si256());
775 uint64_t burst = __builtin_popcountll
777 (_mm256_extracti128_si256
779 burst += __builtin_popcountll
781 (_mm256_castsi256_si128(status0_7)));
783 if (burst != ICE_DESCS_PER_LOOP_AVX)
787 /* update tail pointers */
788 rxq->rx_tail += received;
789 rxq->rx_tail &= (rxq->nb_rx_desc - 1);
790 if ((rxq->rx_tail & 1) == 1 && received > 1) { /* keep avx2 aligned */
794 rxq->rxrearm_nb += received;
800 * - nb_pkts < ICE_DESCS_PER_LOOP, just return no packet
803 ice_recv_pkts_vec_avx512(void *rx_queue, struct rte_mbuf **rx_pkts,
806 return _ice_recv_raw_pkts_vec_avx512(rx_queue, rx_pkts, nb_pkts, NULL);
810 * vPMD receive routine that reassembles single burst of 32 scattered packets
812 * - nb_pkts < ICE_DESCS_PER_LOOP, just return no packet
815 ice_recv_scattered_burst_vec_avx512(void *rx_queue, struct rte_mbuf **rx_pkts,
818 struct ice_rx_queue *rxq = rx_queue;
819 uint8_t split_flags[ICE_VPMD_RX_BURST] = {0};
821 /* get some new buffers */
822 uint16_t nb_bufs = _ice_recv_raw_pkts_vec_avx512(rxq, rx_pkts, nb_pkts,
827 /* happy day case, full burst + no packets to be joined */
828 const uint64_t *split_fl64 = (uint64_t *)split_flags;
830 if (!rxq->pkt_first_seg &&
831 split_fl64[0] == 0 && split_fl64[1] == 0 &&
832 split_fl64[2] == 0 && split_fl64[3] == 0)
835 /* reassemble any packets that need reassembly */
838 if (!rxq->pkt_first_seg) {
839 /* find the first split flag, and only reassemble then */
840 while (i < nb_bufs && !split_flags[i])
844 rxq->pkt_first_seg = rx_pkts[i];
846 return i + ice_rx_reassemble_packets(rxq, &rx_pkts[i], nb_bufs - i,
851 * vPMD receive routine that reassembles scattered packets.
852 * Main receive routine that can handle arbitrary burst sizes
854 * - nb_pkts < ICE_DESCS_PER_LOOP, just return no packet
857 ice_recv_scattered_pkts_vec_avx512(void *rx_queue, struct rte_mbuf **rx_pkts,
862 while (nb_pkts > ICE_VPMD_RX_BURST) {
863 uint16_t burst = ice_recv_scattered_burst_vec_avx512(rx_queue,
864 rx_pkts + retval, ICE_VPMD_RX_BURST);
867 if (burst < ICE_VPMD_RX_BURST)
870 return retval + ice_recv_scattered_burst_vec_avx512(rx_queue,
871 rx_pkts + retval, nb_pkts);
874 static __rte_always_inline int
875 ice_tx_free_bufs_avx512(struct ice_tx_queue *txq)
877 struct ice_vec_tx_entry *txep;
881 struct rte_mbuf *m, *free[ICE_TX_MAX_FREE_BUF_SZ];
883 /* check DD bits on threshold descriptor */
884 if ((txq->tx_ring[txq->tx_next_dd].cmd_type_offset_bsz &
885 rte_cpu_to_le_64(ICE_TXD_QW1_DTYPE_M)) !=
886 rte_cpu_to_le_64(ICE_TX_DESC_DTYPE_DESC_DONE))
889 n = txq->tx_rs_thresh;
891 /* first buffer to free from S/W ring is at index
892 * tx_next_dd - (tx_rs_thresh - 1)
894 txep = (void *)txq->sw_ring;
895 txep += txq->tx_next_dd - (n - 1);
897 if (txq->offloads & DEV_TX_OFFLOAD_MBUF_FAST_FREE && (n & 31) == 0) {
898 struct rte_mempool *mp = txep[0].mbuf->pool;
900 struct rte_mempool_cache *cache = rte_mempool_default_cache(mp,
903 if (!cache || cache->len == 0)
906 cache_objs = &cache->objs[cache->len];
908 if (n > RTE_MEMPOOL_CACHE_MAX_SIZE) {
909 rte_mempool_ops_enqueue_bulk(mp, (void *)txep, n);
913 /* The cache follows the following algorithm
914 * 1. Add the objects to the cache
915 * 2. Anything greater than the cache min value (if it
916 * crosses the cache flush threshold) is flushed to the ring.
918 /* Add elements back into the cache */
920 /* n is multiple of 32 */
922 const __m512i a = _mm512_loadu_si512(&txep[copied]);
923 const __m512i b = _mm512_loadu_si512(&txep[copied + 8]);
924 const __m512i c = _mm512_loadu_si512(&txep[copied + 16]);
925 const __m512i d = _mm512_loadu_si512(&txep[copied + 24]);
927 _mm512_storeu_si512(&cache_objs[copied], a);
928 _mm512_storeu_si512(&cache_objs[copied + 8], b);
929 _mm512_storeu_si512(&cache_objs[copied + 16], c);
930 _mm512_storeu_si512(&cache_objs[copied + 24], d);
935 if (cache->len >= cache->flushthresh) {
936 rte_mempool_ops_enqueue_bulk
937 (mp, &cache->objs[cache->size],
938 cache->len - cache->size);
939 cache->len = cache->size;
945 m = rte_pktmbuf_prefree_seg(txep[0].mbuf);
949 for (i = 1; i < n; i++) {
950 m = rte_pktmbuf_prefree_seg(txep[i].mbuf);
952 if (likely(m->pool == free[0]->pool)) {
955 rte_mempool_put_bulk(free[0]->pool,
963 rte_mempool_put_bulk(free[0]->pool, (void **)free, nb_free);
965 for (i = 1; i < n; i++) {
966 m = rte_pktmbuf_prefree_seg(txep[i].mbuf);
968 rte_mempool_put(m->pool, m);
973 /* buffers were freed, update counters */
974 txq->nb_tx_free = (uint16_t)(txq->nb_tx_free + txq->tx_rs_thresh);
975 txq->tx_next_dd = (uint16_t)(txq->tx_next_dd + txq->tx_rs_thresh);
976 if (txq->tx_next_dd >= txq->nb_tx_desc)
977 txq->tx_next_dd = (uint16_t)(txq->tx_rs_thresh - 1);
979 return txq->tx_rs_thresh;
983 ice_vtx1(volatile struct ice_tx_desc *txdp,
984 struct rte_mbuf *pkt, uint64_t flags)
987 (ICE_TX_DESC_DTYPE_DATA |
988 ((uint64_t)flags << ICE_TXD_QW1_CMD_S) |
989 ((uint64_t)pkt->data_len << ICE_TXD_QW1_TX_BUF_SZ_S));
991 __m128i descriptor = _mm_set_epi64x(high_qw,
992 pkt->buf_iova + pkt->data_off);
993 _mm_store_si128((__m128i *)txdp, descriptor);
997 ice_vtx(volatile struct ice_tx_desc *txdp,
998 struct rte_mbuf **pkt, uint16_t nb_pkts, uint64_t flags)
1000 const uint64_t hi_qw_tmpl = (ICE_TX_DESC_DTYPE_DATA |
1001 ((uint64_t)flags << ICE_TXD_QW1_CMD_S));
1003 for (; nb_pkts > 3; txdp += 4, pkt += 4, nb_pkts -= 4) {
1006 ((uint64_t)pkt[3]->data_len <<
1007 ICE_TXD_QW1_TX_BUF_SZ_S);
1010 ((uint64_t)pkt[2]->data_len <<
1011 ICE_TXD_QW1_TX_BUF_SZ_S);
1014 ((uint64_t)pkt[1]->data_len <<
1015 ICE_TXD_QW1_TX_BUF_SZ_S);
1018 ((uint64_t)pkt[0]->data_len <<
1019 ICE_TXD_QW1_TX_BUF_SZ_S);
1024 pkt[3]->buf_iova + pkt[3]->data_off,
1026 pkt[2]->buf_iova + pkt[2]->data_off,
1028 pkt[1]->buf_iova + pkt[1]->data_off,
1030 pkt[0]->buf_iova + pkt[0]->data_off);
1031 _mm512_storeu_si512((void *)txdp, desc0_3);
1034 /* do any last ones */
1036 ice_vtx1(txdp, *pkt, flags);
1037 txdp++, pkt++, nb_pkts--;
1041 static __rte_always_inline void
1042 ice_tx_backlog_entry_avx512(struct ice_vec_tx_entry *txep,
1043 struct rte_mbuf **tx_pkts, uint16_t nb_pkts)
1047 for (i = 0; i < (int)nb_pkts; ++i)
1048 txep[i].mbuf = tx_pkts[i];
1051 static inline uint16_t
1052 ice_xmit_fixed_burst_vec_avx512(void *tx_queue, struct rte_mbuf **tx_pkts,
1055 struct ice_tx_queue *txq = (struct ice_tx_queue *)tx_queue;
1056 volatile struct ice_tx_desc *txdp;
1057 struct ice_vec_tx_entry *txep;
1058 uint16_t n, nb_commit, tx_id;
1059 uint64_t flags = ICE_TD_CMD;
1060 uint64_t rs = ICE_TX_DESC_CMD_RS | ICE_TD_CMD;
1062 /* cross rx_thresh boundary is not allowed */
1063 nb_pkts = RTE_MIN(nb_pkts, txq->tx_rs_thresh);
1065 if (txq->nb_tx_free < txq->tx_free_thresh)
1066 ice_tx_free_bufs_avx512(txq);
1068 nb_commit = nb_pkts = (uint16_t)RTE_MIN(txq->nb_tx_free, nb_pkts);
1069 if (unlikely(nb_pkts == 0))
1072 tx_id = txq->tx_tail;
1073 txdp = &txq->tx_ring[tx_id];
1074 txep = (void *)txq->sw_ring;
1077 txq->nb_tx_free = (uint16_t)(txq->nb_tx_free - nb_pkts);
1079 n = (uint16_t)(txq->nb_tx_desc - tx_id);
1080 if (nb_commit >= n) {
1081 ice_tx_backlog_entry_avx512(txep, tx_pkts, n);
1083 ice_vtx(txdp, tx_pkts, n - 1, flags);
1087 ice_vtx1(txdp, *tx_pkts++, rs);
1089 nb_commit = (uint16_t)(nb_commit - n);
1092 txq->tx_next_rs = (uint16_t)(txq->tx_rs_thresh - 1);
1094 /* avoid reach the end of ring */
1095 txdp = txq->tx_ring;
1096 txep = (void *)txq->sw_ring;
1099 ice_tx_backlog_entry_avx512(txep, tx_pkts, nb_commit);
1101 ice_vtx(txdp, tx_pkts, nb_commit, flags);
1103 tx_id = (uint16_t)(tx_id + nb_commit);
1104 if (tx_id > txq->tx_next_rs) {
1105 txq->tx_ring[txq->tx_next_rs].cmd_type_offset_bsz |=
1106 rte_cpu_to_le_64(((uint64_t)ICE_TX_DESC_CMD_RS) <<
1109 (uint16_t)(txq->tx_next_rs + txq->tx_rs_thresh);
1112 txq->tx_tail = tx_id;
1114 ICE_PCI_REG_WRITE(txq->qtx_tail, txq->tx_tail);
1120 ice_xmit_pkts_vec_avx512(void *tx_queue, struct rte_mbuf **tx_pkts,
1124 struct ice_tx_queue *txq = (struct ice_tx_queue *)tx_queue;
1129 num = (uint16_t)RTE_MIN(nb_pkts, txq->tx_rs_thresh);
1130 ret = ice_xmit_fixed_burst_vec_avx512(tx_queue,
1131 &tx_pkts[nb_tx], num);