1 // SPDX-License-Identifier: GPL-2.0 2 /* Copyright(c) 2013 - 2018 Intel Corporation. */ 3 4 #include <linux/prefetch.h> 5 6 #include "iavf.h" 7 #include "iavf_trace.h" 8 #include "iavf_prototype.h" 9 10 static inline __le64 build_ctob(u32 td_cmd, u32 td_offset, unsigned int size, 11 u32 td_tag) 12 { 13 return cpu_to_le64(IAVF_TX_DESC_DTYPE_DATA | 14 ((u64)td_cmd << IAVF_TXD_QW1_CMD_SHIFT) | 15 ((u64)td_offset << IAVF_TXD_QW1_OFFSET_SHIFT) | 16 ((u64)size << IAVF_TXD_QW1_TX_BUF_SZ_SHIFT) | 17 ((u64)td_tag << IAVF_TXD_QW1_L2TAG1_SHIFT)); 18 } 19 20 #define IAVF_TXD_CMD (IAVF_TX_DESC_CMD_EOP | IAVF_TX_DESC_CMD_RS) 21 22 /** 23 * iavf_unmap_and_free_tx_resource - Release a Tx buffer 24 * @ring: the ring that owns the buffer 25 * @tx_buffer: the buffer to free 26 **/ 27 static void iavf_unmap_and_free_tx_resource(struct iavf_ring *ring, 28 struct iavf_tx_buffer *tx_buffer) 29 { 30 if (tx_buffer->skb) { 31 if (tx_buffer->tx_flags & IAVF_TX_FLAGS_FD_SB) 32 kfree(tx_buffer->raw_buf); 33 else 34 dev_kfree_skb_any(tx_buffer->skb); 35 if (dma_unmap_len(tx_buffer, len)) 36 dma_unmap_single(ring->dev, 37 dma_unmap_addr(tx_buffer, dma), 38 dma_unmap_len(tx_buffer, len), 39 DMA_TO_DEVICE); 40 } else if (dma_unmap_len(tx_buffer, len)) { 41 dma_unmap_page(ring->dev, 42 dma_unmap_addr(tx_buffer, dma), 43 dma_unmap_len(tx_buffer, len), 44 DMA_TO_DEVICE); 45 } 46 47 tx_buffer->next_to_watch = NULL; 48 tx_buffer->skb = NULL; 49 dma_unmap_len_set(tx_buffer, len, 0); 50 /* tx_buffer must be completely set up in the transmit path */ 51 } 52 53 /** 54 * iavf_clean_tx_ring - Free any empty Tx buffers 55 * @tx_ring: ring to be cleaned 56 **/ 57 void iavf_clean_tx_ring(struct iavf_ring *tx_ring) 58 { 59 unsigned long bi_size; 60 u16 i; 61 62 /* ring already cleared, nothing to do */ 63 if (!tx_ring->tx_bi) 64 return; 65 66 /* Free all the Tx ring sk_buffs */ 67 for (i = 0; i < tx_ring->count; i++) 68 iavf_unmap_and_free_tx_resource(tx_ring, &tx_ring->tx_bi[i]); 69 70 bi_size = sizeof(struct iavf_tx_buffer) * tx_ring->count; 71 memset(tx_ring->tx_bi, 0, bi_size); 72 73 /* Zero out the descriptor ring */ 74 memset(tx_ring->desc, 0, tx_ring->size); 75 76 tx_ring->next_to_use = 0; 77 tx_ring->next_to_clean = 0; 78 79 if (!tx_ring->netdev) 80 return; 81 82 /* cleanup Tx queue statistics */ 83 netdev_tx_reset_queue(txring_txq(tx_ring)); 84 } 85 86 /** 87 * iavf_free_tx_resources - Free Tx resources per queue 88 * @tx_ring: Tx descriptor ring for a specific queue 89 * 90 * Free all transmit software resources 91 **/ 92 void iavf_free_tx_resources(struct iavf_ring *tx_ring) 93 { 94 iavf_clean_tx_ring(tx_ring); 95 kfree(tx_ring->tx_bi); 96 tx_ring->tx_bi = NULL; 97 98 if (tx_ring->desc) { 99 dma_free_coherent(tx_ring->dev, tx_ring->size, 100 tx_ring->desc, tx_ring->dma); 101 tx_ring->desc = NULL; 102 } 103 } 104 105 /** 106 * iavf_get_tx_pending - how many Tx descriptors not processed 107 * @ring: the ring of descriptors 108 * @in_sw: is tx_pending being checked in SW or HW 109 * 110 * Since there is no access to the ring head register 111 * in XL710, we need to use our local copies 112 **/ 113 u32 iavf_get_tx_pending(struct iavf_ring *ring, bool in_sw) 114 { 115 u32 head, tail; 116 117 head = ring->next_to_clean; 118 tail = readl(ring->tail); 119 120 if (head != tail) 121 return (head < tail) ? 122 tail - head : (tail + ring->count - head); 123 124 return 0; 125 } 126 127 /** 128 * iavf_detect_recover_hung - Function to detect and recover hung_queues 129 * @vsi: pointer to vsi struct with tx queues 130 * 131 * VSI has netdev and netdev has TX queues. This function is to check each of 132 * those TX queues if they are hung, trigger recovery by issuing SW interrupt. 133 **/ 134 void iavf_detect_recover_hung(struct iavf_vsi *vsi) 135 { 136 struct iavf_ring *tx_ring = NULL; 137 struct net_device *netdev; 138 unsigned int i; 139 int packets; 140 141 if (!vsi) 142 return; 143 144 if (test_bit(__IAVF_VSI_DOWN, vsi->state)) 145 return; 146 147 netdev = vsi->netdev; 148 if (!netdev) 149 return; 150 151 if (!netif_carrier_ok(netdev)) 152 return; 153 154 for (i = 0; i < vsi->back->num_active_queues; i++) { 155 tx_ring = &vsi->back->tx_rings[i]; 156 if (tx_ring && tx_ring->desc) { 157 /* If packet counter has not changed the queue is 158 * likely stalled, so force an interrupt for this 159 * queue. 160 * 161 * prev_pkt_ctr would be negative if there was no 162 * pending work. 163 */ 164 packets = tx_ring->stats.packets & INT_MAX; 165 if (tx_ring->tx_stats.prev_pkt_ctr == packets) { 166 iavf_force_wb(vsi, tx_ring->q_vector); 167 continue; 168 } 169 170 /* Memory barrier between read of packet count and call 171 * to iavf_get_tx_pending() 172 */ 173 smp_rmb(); 174 tx_ring->tx_stats.prev_pkt_ctr = 175 iavf_get_tx_pending(tx_ring, true) ? packets : -1; 176 } 177 } 178 } 179 180 #define WB_STRIDE 4 181 182 /** 183 * iavf_clean_tx_irq - Reclaim resources after transmit completes 184 * @vsi: the VSI we care about 185 * @tx_ring: Tx ring to clean 186 * @napi_budget: Used to determine if we are in netpoll 187 * 188 * Returns true if there's any budget left (e.g. the clean is finished) 189 **/ 190 static bool iavf_clean_tx_irq(struct iavf_vsi *vsi, 191 struct iavf_ring *tx_ring, int napi_budget) 192 { 193 int i = tx_ring->next_to_clean; 194 struct iavf_tx_buffer *tx_buf; 195 struct iavf_tx_desc *tx_desc; 196 unsigned int total_bytes = 0, total_packets = 0; 197 unsigned int budget = vsi->work_limit; 198 199 tx_buf = &tx_ring->tx_bi[i]; 200 tx_desc = IAVF_TX_DESC(tx_ring, i); 201 i -= tx_ring->count; 202 203 do { 204 struct iavf_tx_desc *eop_desc = tx_buf->next_to_watch; 205 206 /* if next_to_watch is not set then there is no work pending */ 207 if (!eop_desc) 208 break; 209 210 /* prevent any other reads prior to eop_desc */ 211 smp_rmb(); 212 213 iavf_trace(clean_tx_irq, tx_ring, tx_desc, tx_buf); 214 /* if the descriptor isn't done, no work yet to do */ 215 if (!(eop_desc->cmd_type_offset_bsz & 216 cpu_to_le64(IAVF_TX_DESC_DTYPE_DESC_DONE))) 217 break; 218 219 /* clear next_to_watch to prevent false hangs */ 220 tx_buf->next_to_watch = NULL; 221 222 /* update the statistics for this packet */ 223 total_bytes += tx_buf->bytecount; 224 total_packets += tx_buf->gso_segs; 225 226 /* free the skb */ 227 napi_consume_skb(tx_buf->skb, napi_budget); 228 229 /* unmap skb header data */ 230 dma_unmap_single(tx_ring->dev, 231 dma_unmap_addr(tx_buf, dma), 232 dma_unmap_len(tx_buf, len), 233 DMA_TO_DEVICE); 234 235 /* clear tx_buffer data */ 236 tx_buf->skb = NULL; 237 dma_unmap_len_set(tx_buf, len, 0); 238 239 /* unmap remaining buffers */ 240 while (tx_desc != eop_desc) { 241 iavf_trace(clean_tx_irq_unmap, 242 tx_ring, tx_desc, tx_buf); 243 244 tx_buf++; 245 tx_desc++; 246 i++; 247 if (unlikely(!i)) { 248 i -= tx_ring->count; 249 tx_buf = tx_ring->tx_bi; 250 tx_desc = IAVF_TX_DESC(tx_ring, 0); 251 } 252 253 /* unmap any remaining paged data */ 254 if (dma_unmap_len(tx_buf, len)) { 255 dma_unmap_page(tx_ring->dev, 256 dma_unmap_addr(tx_buf, dma), 257 dma_unmap_len(tx_buf, len), 258 DMA_TO_DEVICE); 259 dma_unmap_len_set(tx_buf, len, 0); 260 } 261 } 262 263 /* move us one more past the eop_desc for start of next pkt */ 264 tx_buf++; 265 tx_desc++; 266 i++; 267 if (unlikely(!i)) { 268 i -= tx_ring->count; 269 tx_buf = tx_ring->tx_bi; 270 tx_desc = IAVF_TX_DESC(tx_ring, 0); 271 } 272 273 prefetch(tx_desc); 274 275 /* update budget accounting */ 276 budget--; 277 } while (likely(budget)); 278 279 i += tx_ring->count; 280 tx_ring->next_to_clean = i; 281 u64_stats_update_begin(&tx_ring->syncp); 282 tx_ring->stats.bytes += total_bytes; 283 tx_ring->stats.packets += total_packets; 284 u64_stats_update_end(&tx_ring->syncp); 285 tx_ring->q_vector->tx.total_bytes += total_bytes; 286 tx_ring->q_vector->tx.total_packets += total_packets; 287 288 if (tx_ring->flags & IAVF_TXR_FLAGS_WB_ON_ITR) { 289 /* check to see if there are < 4 descriptors 290 * waiting to be written back, then kick the hardware to force 291 * them to be written back in case we stay in NAPI. 292 * In this mode on X722 we do not enable Interrupt. 293 */ 294 unsigned int j = iavf_get_tx_pending(tx_ring, false); 295 296 if (budget && 297 ((j / WB_STRIDE) == 0) && (j > 0) && 298 !test_bit(__IAVF_VSI_DOWN, vsi->state) && 299 (IAVF_DESC_UNUSED(tx_ring) != tx_ring->count)) 300 tx_ring->arm_wb = true; 301 } 302 303 /* notify netdev of completed buffers */ 304 netdev_tx_completed_queue(txring_txq(tx_ring), 305 total_packets, total_bytes); 306 307 #define TX_WAKE_THRESHOLD ((s16)(DESC_NEEDED * 2)) 308 if (unlikely(total_packets && netif_carrier_ok(tx_ring->netdev) && 309 (IAVF_DESC_UNUSED(tx_ring) >= TX_WAKE_THRESHOLD))) { 310 /* Make sure that anybody stopping the queue after this 311 * sees the new next_to_clean. 312 */ 313 smp_mb(); 314 if (__netif_subqueue_stopped(tx_ring->netdev, 315 tx_ring->queue_index) && 316 !test_bit(__IAVF_VSI_DOWN, vsi->state)) { 317 netif_wake_subqueue(tx_ring->netdev, 318 tx_ring->queue_index); 319 ++tx_ring->tx_stats.restart_queue; 320 } 321 } 322 323 return !!budget; 324 } 325 326 /** 327 * iavf_enable_wb_on_itr - Arm hardware to do a wb, interrupts are not enabled 328 * @vsi: the VSI we care about 329 * @q_vector: the vector on which to enable writeback 330 * 331 **/ 332 static void iavf_enable_wb_on_itr(struct iavf_vsi *vsi, 333 struct iavf_q_vector *q_vector) 334 { 335 u16 flags = q_vector->tx.ring[0].flags; 336 u32 val; 337 338 if (!(flags & IAVF_TXR_FLAGS_WB_ON_ITR)) 339 return; 340 341 if (q_vector->arm_wb_state) 342 return; 343 344 val = IAVF_VFINT_DYN_CTLN1_WB_ON_ITR_MASK | 345 IAVF_VFINT_DYN_CTLN1_ITR_INDX_MASK; /* set noitr */ 346 347 wr32(&vsi->back->hw, 348 IAVF_VFINT_DYN_CTLN1(q_vector->reg_idx), val); 349 q_vector->arm_wb_state = true; 350 } 351 352 /** 353 * iavf_force_wb - Issue SW Interrupt so HW does a wb 354 * @vsi: the VSI we care about 355 * @q_vector: the vector on which to force writeback 356 * 357 **/ 358 void iavf_force_wb(struct iavf_vsi *vsi, struct iavf_q_vector *q_vector) 359 { 360 u32 val = IAVF_VFINT_DYN_CTLN1_INTENA_MASK | 361 IAVF_VFINT_DYN_CTLN1_ITR_INDX_MASK | /* set noitr */ 362 IAVF_VFINT_DYN_CTLN1_SWINT_TRIG_MASK | 363 IAVF_VFINT_DYN_CTLN1_SW_ITR_INDX_ENA_MASK 364 /* allow 00 to be written to the index */; 365 366 wr32(&vsi->back->hw, 367 IAVF_VFINT_DYN_CTLN1(q_vector->reg_idx), 368 val); 369 } 370 371 static inline bool iavf_container_is_rx(struct iavf_q_vector *q_vector, 372 struct iavf_ring_container *rc) 373 { 374 return &q_vector->rx == rc; 375 } 376 377 static inline unsigned int iavf_itr_divisor(struct iavf_q_vector *q_vector) 378 { 379 unsigned int divisor; 380 381 switch (q_vector->adapter->link_speed) { 382 case VIRTCHNL_LINK_SPEED_40GB: 383 divisor = IAVF_ITR_ADAPTIVE_MIN_INC * 1024; 384 break; 385 case VIRTCHNL_LINK_SPEED_25GB: 386 case VIRTCHNL_LINK_SPEED_20GB: 387 divisor = IAVF_ITR_ADAPTIVE_MIN_INC * 512; 388 break; 389 default: 390 case VIRTCHNL_LINK_SPEED_10GB: 391 divisor = IAVF_ITR_ADAPTIVE_MIN_INC * 256; 392 break; 393 case VIRTCHNL_LINK_SPEED_1GB: 394 case VIRTCHNL_LINK_SPEED_100MB: 395 divisor = IAVF_ITR_ADAPTIVE_MIN_INC * 32; 396 break; 397 } 398 399 return divisor; 400 } 401 402 /** 403 * iavf_update_itr - update the dynamic ITR value based on statistics 404 * @q_vector: structure containing interrupt and ring information 405 * @rc: structure containing ring performance data 406 * 407 * Stores a new ITR value based on packets and byte 408 * counts during the last interrupt. The advantage of per interrupt 409 * computation is faster updates and more accurate ITR for the current 410 * traffic pattern. Constants in this function were computed 411 * based on theoretical maximum wire speed and thresholds were set based 412 * on testing data as well as attempting to minimize response time 413 * while increasing bulk throughput. 414 **/ 415 static void iavf_update_itr(struct iavf_q_vector *q_vector, 416 struct iavf_ring_container *rc) 417 { 418 unsigned int avg_wire_size, packets, bytes, itr; 419 unsigned long next_update = jiffies; 420 421 /* If we don't have any rings just leave ourselves set for maximum 422 * possible latency so we take ourselves out of the equation. 423 */ 424 if (!rc->ring || !ITR_IS_DYNAMIC(rc->ring->itr_setting)) 425 return; 426 427 /* For Rx we want to push the delay up and default to low latency. 428 * for Tx we want to pull the delay down and default to high latency. 429 */ 430 itr = iavf_container_is_rx(q_vector, rc) ? 431 IAVF_ITR_ADAPTIVE_MIN_USECS | IAVF_ITR_ADAPTIVE_LATENCY : 432 IAVF_ITR_ADAPTIVE_MAX_USECS | IAVF_ITR_ADAPTIVE_LATENCY; 433 434 /* If we didn't update within up to 1 - 2 jiffies we can assume 435 * that either packets are coming in so slow there hasn't been 436 * any work, or that there is so much work that NAPI is dealing 437 * with interrupt moderation and we don't need to do anything. 438 */ 439 if (time_after(next_update, rc->next_update)) 440 goto clear_counts; 441 442 /* If itr_countdown is set it means we programmed an ITR within 443 * the last 4 interrupt cycles. This has a side effect of us 444 * potentially firing an early interrupt. In order to work around 445 * this we need to throw out any data received for a few 446 * interrupts following the update. 447 */ 448 if (q_vector->itr_countdown) { 449 itr = rc->target_itr; 450 goto clear_counts; 451 } 452 453 packets = rc->total_packets; 454 bytes = rc->total_bytes; 455 456 if (iavf_container_is_rx(q_vector, rc)) { 457 /* If Rx there are 1 to 4 packets and bytes are less than 458 * 9000 assume insufficient data to use bulk rate limiting 459 * approach unless Tx is already in bulk rate limiting. We 460 * are likely latency driven. 461 */ 462 if (packets && packets < 4 && bytes < 9000 && 463 (q_vector->tx.target_itr & IAVF_ITR_ADAPTIVE_LATENCY)) { 464 itr = IAVF_ITR_ADAPTIVE_LATENCY; 465 goto adjust_by_size; 466 } 467 } else if (packets < 4) { 468 /* If we have Tx and Rx ITR maxed and Tx ITR is running in 469 * bulk mode and we are receiving 4 or fewer packets just 470 * reset the ITR_ADAPTIVE_LATENCY bit for latency mode so 471 * that the Rx can relax. 472 */ 473 if (rc->target_itr == IAVF_ITR_ADAPTIVE_MAX_USECS && 474 (q_vector->rx.target_itr & IAVF_ITR_MASK) == 475 IAVF_ITR_ADAPTIVE_MAX_USECS) 476 goto clear_counts; 477 } else if (packets > 32) { 478 /* If we have processed over 32 packets in a single interrupt 479 * for Tx assume we need to switch over to "bulk" mode. 480 */ 481 rc->target_itr &= ~IAVF_ITR_ADAPTIVE_LATENCY; 482 } 483 484 /* We have no packets to actually measure against. This means 485 * either one of the other queues on this vector is active or 486 * we are a Tx queue doing TSO with too high of an interrupt rate. 487 * 488 * Between 4 and 56 we can assume that our current interrupt delay 489 * is only slightly too low. As such we should increase it by a small 490 * fixed amount. 491 */ 492 if (packets < 56) { 493 itr = rc->target_itr + IAVF_ITR_ADAPTIVE_MIN_INC; 494 if ((itr & IAVF_ITR_MASK) > IAVF_ITR_ADAPTIVE_MAX_USECS) { 495 itr &= IAVF_ITR_ADAPTIVE_LATENCY; 496 itr += IAVF_ITR_ADAPTIVE_MAX_USECS; 497 } 498 goto clear_counts; 499 } 500 501 if (packets <= 256) { 502 itr = min(q_vector->tx.current_itr, q_vector->rx.current_itr); 503 itr &= IAVF_ITR_MASK; 504 505 /* Between 56 and 112 is our "goldilocks" zone where we are 506 * working out "just right". Just report that our current 507 * ITR is good for us. 508 */ 509 if (packets <= 112) 510 goto clear_counts; 511 512 /* If packet count is 128 or greater we are likely looking 513 * at a slight overrun of the delay we want. Try halving 514 * our delay to see if that will cut the number of packets 515 * in half per interrupt. 516 */ 517 itr /= 2; 518 itr &= IAVF_ITR_MASK; 519 if (itr < IAVF_ITR_ADAPTIVE_MIN_USECS) 520 itr = IAVF_ITR_ADAPTIVE_MIN_USECS; 521 522 goto clear_counts; 523 } 524 525 /* The paths below assume we are dealing with a bulk ITR since 526 * number of packets is greater than 256. We are just going to have 527 * to compute a value and try to bring the count under control, 528 * though for smaller packet sizes there isn't much we can do as 529 * NAPI polling will likely be kicking in sooner rather than later. 530 */ 531 itr = IAVF_ITR_ADAPTIVE_BULK; 532 533 adjust_by_size: 534 /* If packet counts are 256 or greater we can assume we have a gross 535 * overestimation of what the rate should be. Instead of trying to fine 536 * tune it just use the formula below to try and dial in an exact value 537 * give the current packet size of the frame. 538 */ 539 avg_wire_size = bytes / packets; 540 541 /* The following is a crude approximation of: 542 * wmem_default / (size + overhead) = desired_pkts_per_int 543 * rate / bits_per_byte / (size + ethernet overhead) = pkt_rate 544 * (desired_pkt_rate / pkt_rate) * usecs_per_sec = ITR value 545 * 546 * Assuming wmem_default is 212992 and overhead is 640 bytes per 547 * packet, (256 skb, 64 headroom, 320 shared info), we can reduce the 548 * formula down to 549 * 550 * (170 * (size + 24)) / (size + 640) = ITR 551 * 552 * We first do some math on the packet size and then finally bitshift 553 * by 8 after rounding up. We also have to account for PCIe link speed 554 * difference as ITR scales based on this. 555 */ 556 if (avg_wire_size <= 60) { 557 /* Start at 250k ints/sec */ 558 avg_wire_size = 4096; 559 } else if (avg_wire_size <= 380) { 560 /* 250K ints/sec to 60K ints/sec */ 561 avg_wire_size *= 40; 562 avg_wire_size += 1696; 563 } else if (avg_wire_size <= 1084) { 564 /* 60K ints/sec to 36K ints/sec */ 565 avg_wire_size *= 15; 566 avg_wire_size += 11452; 567 } else if (avg_wire_size <= 1980) { 568 /* 36K ints/sec to 30K ints/sec */ 569 avg_wire_size *= 5; 570 avg_wire_size += 22420; 571 } else { 572 /* plateau at a limit of 30K ints/sec */ 573 avg_wire_size = 32256; 574 } 575 576 /* If we are in low latency mode halve our delay which doubles the 577 * rate to somewhere between 100K to 16K ints/sec 578 */ 579 if (itr & IAVF_ITR_ADAPTIVE_LATENCY) 580 avg_wire_size /= 2; 581 582 /* Resultant value is 256 times larger than it needs to be. This 583 * gives us room to adjust the value as needed to either increase 584 * or decrease the value based on link speeds of 10G, 2.5G, 1G, etc. 585 * 586 * Use addition as we have already recorded the new latency flag 587 * for the ITR value. 588 */ 589 itr += DIV_ROUND_UP(avg_wire_size, iavf_itr_divisor(q_vector)) * 590 IAVF_ITR_ADAPTIVE_MIN_INC; 591 592 if ((itr & IAVF_ITR_MASK) > IAVF_ITR_ADAPTIVE_MAX_USECS) { 593 itr &= IAVF_ITR_ADAPTIVE_LATENCY; 594 itr += IAVF_ITR_ADAPTIVE_MAX_USECS; 595 } 596 597 clear_counts: 598 /* write back value */ 599 rc->target_itr = itr; 600 601 /* next update should occur within next jiffy */ 602 rc->next_update = next_update + 1; 603 604 rc->total_bytes = 0; 605 rc->total_packets = 0; 606 } 607 608 /** 609 * iavf_setup_tx_descriptors - Allocate the Tx descriptors 610 * @tx_ring: the tx ring to set up 611 * 612 * Return 0 on success, negative on error 613 **/ 614 int iavf_setup_tx_descriptors(struct iavf_ring *tx_ring) 615 { 616 struct device *dev = tx_ring->dev; 617 int bi_size; 618 619 if (!dev) 620 return -ENOMEM; 621 622 /* warn if we are about to overwrite the pointer */ 623 WARN_ON(tx_ring->tx_bi); 624 bi_size = sizeof(struct iavf_tx_buffer) * tx_ring->count; 625 tx_ring->tx_bi = kzalloc(bi_size, GFP_KERNEL); 626 if (!tx_ring->tx_bi) 627 goto err; 628 629 /* round up to nearest 4K */ 630 tx_ring->size = tx_ring->count * sizeof(struct iavf_tx_desc); 631 tx_ring->size = ALIGN(tx_ring->size, 4096); 632 tx_ring->desc = dma_alloc_coherent(dev, tx_ring->size, 633 &tx_ring->dma, GFP_KERNEL); 634 if (!tx_ring->desc) { 635 dev_info(dev, "Unable to allocate memory for the Tx descriptor ring, size=%d\n", 636 tx_ring->size); 637 goto err; 638 } 639 640 tx_ring->next_to_use = 0; 641 tx_ring->next_to_clean = 0; 642 tx_ring->tx_stats.prev_pkt_ctr = -1; 643 return 0; 644 645 err: 646 kfree(tx_ring->tx_bi); 647 tx_ring->tx_bi = NULL; 648 return -ENOMEM; 649 } 650 651 /** 652 * iavf_clean_rx_ring - Free Rx buffers 653 * @rx_ring: ring to be cleaned 654 **/ 655 void iavf_clean_rx_ring(struct iavf_ring *rx_ring) 656 { 657 unsigned long bi_size; 658 u16 i; 659 660 /* ring already cleared, nothing to do */ 661 if (!rx_ring->rx_bi) 662 return; 663 664 if (rx_ring->skb) { 665 dev_kfree_skb(rx_ring->skb); 666 rx_ring->skb = NULL; 667 } 668 669 /* Free all the Rx ring sk_buffs */ 670 for (i = 0; i < rx_ring->count; i++) { 671 struct iavf_rx_buffer *rx_bi = &rx_ring->rx_bi[i]; 672 673 if (!rx_bi->page) 674 continue; 675 676 /* Invalidate cache lines that may have been written to by 677 * device so that we avoid corrupting memory. 678 */ 679 dma_sync_single_range_for_cpu(rx_ring->dev, 680 rx_bi->dma, 681 rx_bi->page_offset, 682 rx_ring->rx_buf_len, 683 DMA_FROM_DEVICE); 684 685 /* free resources associated with mapping */ 686 dma_unmap_page_attrs(rx_ring->dev, rx_bi->dma, 687 iavf_rx_pg_size(rx_ring), 688 DMA_FROM_DEVICE, 689 IAVF_RX_DMA_ATTR); 690 691 __page_frag_cache_drain(rx_bi->page, rx_bi->pagecnt_bias); 692 693 rx_bi->page = NULL; 694 rx_bi->page_offset = 0; 695 } 696 697 bi_size = sizeof(struct iavf_rx_buffer) * rx_ring->count; 698 memset(rx_ring->rx_bi, 0, bi_size); 699 700 /* Zero out the descriptor ring */ 701 memset(rx_ring->desc, 0, rx_ring->size); 702 703 rx_ring->next_to_alloc = 0; 704 rx_ring->next_to_clean = 0; 705 rx_ring->next_to_use = 0; 706 } 707 708 /** 709 * iavf_free_rx_resources - Free Rx resources 710 * @rx_ring: ring to clean the resources from 711 * 712 * Free all receive software resources 713 **/ 714 void iavf_free_rx_resources(struct iavf_ring *rx_ring) 715 { 716 iavf_clean_rx_ring(rx_ring); 717 kfree(rx_ring->rx_bi); 718 rx_ring->rx_bi = NULL; 719 720 if (rx_ring->desc) { 721 dma_free_coherent(rx_ring->dev, rx_ring->size, 722 rx_ring->desc, rx_ring->dma); 723 rx_ring->desc = NULL; 724 } 725 } 726 727 /** 728 * iavf_setup_rx_descriptors - Allocate Rx descriptors 729 * @rx_ring: Rx descriptor ring (for a specific queue) to setup 730 * 731 * Returns 0 on success, negative on failure 732 **/ 733 int iavf_setup_rx_descriptors(struct iavf_ring *rx_ring) 734 { 735 struct device *dev = rx_ring->dev; 736 int bi_size; 737 738 /* warn if we are about to overwrite the pointer */ 739 WARN_ON(rx_ring->rx_bi); 740 bi_size = sizeof(struct iavf_rx_buffer) * rx_ring->count; 741 rx_ring->rx_bi = kzalloc(bi_size, GFP_KERNEL); 742 if (!rx_ring->rx_bi) 743 goto err; 744 745 u64_stats_init(&rx_ring->syncp); 746 747 /* Round up to nearest 4K */ 748 rx_ring->size = rx_ring->count * sizeof(union iavf_32byte_rx_desc); 749 rx_ring->size = ALIGN(rx_ring->size, 4096); 750 rx_ring->desc = dma_alloc_coherent(dev, rx_ring->size, 751 &rx_ring->dma, GFP_KERNEL); 752 753 if (!rx_ring->desc) { 754 dev_info(dev, "Unable to allocate memory for the Rx descriptor ring, size=%d\n", 755 rx_ring->size); 756 goto err; 757 } 758 759 rx_ring->next_to_alloc = 0; 760 rx_ring->next_to_clean = 0; 761 rx_ring->next_to_use = 0; 762 763 return 0; 764 err: 765 kfree(rx_ring->rx_bi); 766 rx_ring->rx_bi = NULL; 767 return -ENOMEM; 768 } 769 770 /** 771 * iavf_release_rx_desc - Store the new tail and head values 772 * @rx_ring: ring to bump 773 * @val: new head index 774 **/ 775 static inline void iavf_release_rx_desc(struct iavf_ring *rx_ring, u32 val) 776 { 777 rx_ring->next_to_use = val; 778 779 /* update next to alloc since we have filled the ring */ 780 rx_ring->next_to_alloc = val; 781 782 /* Force memory writes to complete before letting h/w 783 * know there are new descriptors to fetch. (Only 784 * applicable for weak-ordered memory model archs, 785 * such as IA-64). 786 */ 787 wmb(); 788 writel(val, rx_ring->tail); 789 } 790 791 /** 792 * iavf_rx_offset - Return expected offset into page to access data 793 * @rx_ring: Ring we are requesting offset of 794 * 795 * Returns the offset value for ring into the data buffer. 796 */ 797 static inline unsigned int iavf_rx_offset(struct iavf_ring *rx_ring) 798 { 799 return ring_uses_build_skb(rx_ring) ? IAVF_SKB_PAD : 0; 800 } 801 802 /** 803 * iavf_alloc_mapped_page - recycle or make a new page 804 * @rx_ring: ring to use 805 * @bi: rx_buffer struct to modify 806 * 807 * Returns true if the page was successfully allocated or 808 * reused. 809 **/ 810 static bool iavf_alloc_mapped_page(struct iavf_ring *rx_ring, 811 struct iavf_rx_buffer *bi) 812 { 813 struct page *page = bi->page; 814 dma_addr_t dma; 815 816 /* since we are recycling buffers we should seldom need to alloc */ 817 if (likely(page)) { 818 rx_ring->rx_stats.page_reuse_count++; 819 return true; 820 } 821 822 /* alloc new page for storage */ 823 page = dev_alloc_pages(iavf_rx_pg_order(rx_ring)); 824 if (unlikely(!page)) { 825 rx_ring->rx_stats.alloc_page_failed++; 826 return false; 827 } 828 829 /* map page for use */ 830 dma = dma_map_page_attrs(rx_ring->dev, page, 0, 831 iavf_rx_pg_size(rx_ring), 832 DMA_FROM_DEVICE, 833 IAVF_RX_DMA_ATTR); 834 835 /* if mapping failed free memory back to system since 836 * there isn't much point in holding memory we can't use 837 */ 838 if (dma_mapping_error(rx_ring->dev, dma)) { 839 __free_pages(page, iavf_rx_pg_order(rx_ring)); 840 rx_ring->rx_stats.alloc_page_failed++; 841 return false; 842 } 843 844 bi->dma = dma; 845 bi->page = page; 846 bi->page_offset = iavf_rx_offset(rx_ring); 847 848 /* initialize pagecnt_bias to 1 representing we fully own page */ 849 bi->pagecnt_bias = 1; 850 851 return true; 852 } 853 854 /** 855 * iavf_receive_skb - Send a completed packet up the stack 856 * @rx_ring: rx ring in play 857 * @skb: packet to send up 858 * @vlan_tag: vlan tag for packet 859 **/ 860 static void iavf_receive_skb(struct iavf_ring *rx_ring, 861 struct sk_buff *skb, u16 vlan_tag) 862 { 863 struct iavf_q_vector *q_vector = rx_ring->q_vector; 864 865 if ((rx_ring->netdev->features & NETIF_F_HW_VLAN_CTAG_RX) && 866 (vlan_tag & VLAN_VID_MASK)) 867 __vlan_hwaccel_put_tag(skb, htons(ETH_P_8021Q), vlan_tag); 868 869 napi_gro_receive(&q_vector->napi, skb); 870 } 871 872 /** 873 * iavf_alloc_rx_buffers - Replace used receive buffers 874 * @rx_ring: ring to place buffers on 875 * @cleaned_count: number of buffers to replace 876 * 877 * Returns false if all allocations were successful, true if any fail 878 **/ 879 bool iavf_alloc_rx_buffers(struct iavf_ring *rx_ring, u16 cleaned_count) 880 { 881 u16 ntu = rx_ring->next_to_use; 882 union iavf_rx_desc *rx_desc; 883 struct iavf_rx_buffer *bi; 884 885 /* do nothing if no valid netdev defined */ 886 if (!rx_ring->netdev || !cleaned_count) 887 return false; 888 889 rx_desc = IAVF_RX_DESC(rx_ring, ntu); 890 bi = &rx_ring->rx_bi[ntu]; 891 892 do { 893 if (!iavf_alloc_mapped_page(rx_ring, bi)) 894 goto no_buffers; 895 896 /* sync the buffer for use by the device */ 897 dma_sync_single_range_for_device(rx_ring->dev, bi->dma, 898 bi->page_offset, 899 rx_ring->rx_buf_len, 900 DMA_FROM_DEVICE); 901 902 /* Refresh the desc even if buffer_addrs didn't change 903 * because each write-back erases this info. 904 */ 905 rx_desc->read.pkt_addr = cpu_to_le64(bi->dma + bi->page_offset); 906 907 rx_desc++; 908 bi++; 909 ntu++; 910 if (unlikely(ntu == rx_ring->count)) { 911 rx_desc = IAVF_RX_DESC(rx_ring, 0); 912 bi = rx_ring->rx_bi; 913 ntu = 0; 914 } 915 916 /* clear the status bits for the next_to_use descriptor */ 917 rx_desc->wb.qword1.status_error_len = 0; 918 919 cleaned_count--; 920 } while (cleaned_count); 921 922 if (rx_ring->next_to_use != ntu) 923 iavf_release_rx_desc(rx_ring, ntu); 924 925 return false; 926 927 no_buffers: 928 if (rx_ring->next_to_use != ntu) 929 iavf_release_rx_desc(rx_ring, ntu); 930 931 /* make sure to come back via polling to try again after 932 * allocation failure 933 */ 934 return true; 935 } 936 937 /** 938 * iavf_rx_checksum - Indicate in skb if hw indicated a good cksum 939 * @vsi: the VSI we care about 940 * @skb: skb currently being received and modified 941 * @rx_desc: the receive descriptor 942 **/ 943 static inline void iavf_rx_checksum(struct iavf_vsi *vsi, 944 struct sk_buff *skb, 945 union iavf_rx_desc *rx_desc) 946 { 947 struct iavf_rx_ptype_decoded decoded; 948 u32 rx_error, rx_status; 949 bool ipv4, ipv6; 950 u8 ptype; 951 u64 qword; 952 953 qword = le64_to_cpu(rx_desc->wb.qword1.status_error_len); 954 ptype = (qword & IAVF_RXD_QW1_PTYPE_MASK) >> IAVF_RXD_QW1_PTYPE_SHIFT; 955 rx_error = (qword & IAVF_RXD_QW1_ERROR_MASK) >> 956 IAVF_RXD_QW1_ERROR_SHIFT; 957 rx_status = (qword & IAVF_RXD_QW1_STATUS_MASK) >> 958 IAVF_RXD_QW1_STATUS_SHIFT; 959 decoded = decode_rx_desc_ptype(ptype); 960 961 skb->ip_summed = CHECKSUM_NONE; 962 963 skb_checksum_none_assert(skb); 964 965 /* Rx csum enabled and ip headers found? */ 966 if (!(vsi->netdev->features & NETIF_F_RXCSUM)) 967 return; 968 969 /* did the hardware decode the packet and checksum? */ 970 if (!(rx_status & BIT(IAVF_RX_DESC_STATUS_L3L4P_SHIFT))) 971 return; 972 973 /* both known and outer_ip must be set for the below code to work */ 974 if (!(decoded.known && decoded.outer_ip)) 975 return; 976 977 ipv4 = (decoded.outer_ip == IAVF_RX_PTYPE_OUTER_IP) && 978 (decoded.outer_ip_ver == IAVF_RX_PTYPE_OUTER_IPV4); 979 ipv6 = (decoded.outer_ip == IAVF_RX_PTYPE_OUTER_IP) && 980 (decoded.outer_ip_ver == IAVF_RX_PTYPE_OUTER_IPV6); 981 982 if (ipv4 && 983 (rx_error & (BIT(IAVF_RX_DESC_ERROR_IPE_SHIFT) | 984 BIT(IAVF_RX_DESC_ERROR_EIPE_SHIFT)))) 985 goto checksum_fail; 986 987 /* likely incorrect csum if alternate IP extension headers found */ 988 if (ipv6 && 989 rx_status & BIT(IAVF_RX_DESC_STATUS_IPV6EXADD_SHIFT)) 990 /* don't increment checksum err here, non-fatal err */ 991 return; 992 993 /* there was some L4 error, count error and punt packet to the stack */ 994 if (rx_error & BIT(IAVF_RX_DESC_ERROR_L4E_SHIFT)) 995 goto checksum_fail; 996 997 /* handle packets that were not able to be checksummed due 998 * to arrival speed, in this case the stack can compute 999 * the csum. 1000 */ 1001 if (rx_error & BIT(IAVF_RX_DESC_ERROR_PPRS_SHIFT)) 1002 return; 1003 1004 /* Only report checksum unnecessary for TCP, UDP, or SCTP */ 1005 switch (decoded.inner_prot) { 1006 case IAVF_RX_PTYPE_INNER_PROT_TCP: 1007 case IAVF_RX_PTYPE_INNER_PROT_UDP: 1008 case IAVF_RX_PTYPE_INNER_PROT_SCTP: 1009 skb->ip_summed = CHECKSUM_UNNECESSARY; 1010 fallthrough; 1011 default: 1012 break; 1013 } 1014 1015 return; 1016 1017 checksum_fail: 1018 vsi->back->hw_csum_rx_error++; 1019 } 1020 1021 /** 1022 * iavf_ptype_to_htype - get a hash type 1023 * @ptype: the ptype value from the descriptor 1024 * 1025 * Returns a hash type to be used by skb_set_hash 1026 **/ 1027 static inline int iavf_ptype_to_htype(u8 ptype) 1028 { 1029 struct iavf_rx_ptype_decoded decoded = decode_rx_desc_ptype(ptype); 1030 1031 if (!decoded.known) 1032 return PKT_HASH_TYPE_NONE; 1033 1034 if (decoded.outer_ip == IAVF_RX_PTYPE_OUTER_IP && 1035 decoded.payload_layer == IAVF_RX_PTYPE_PAYLOAD_LAYER_PAY4) 1036 return PKT_HASH_TYPE_L4; 1037 else if (decoded.outer_ip == IAVF_RX_PTYPE_OUTER_IP && 1038 decoded.payload_layer == IAVF_RX_PTYPE_PAYLOAD_LAYER_PAY3) 1039 return PKT_HASH_TYPE_L3; 1040 else 1041 return PKT_HASH_TYPE_L2; 1042 } 1043 1044 /** 1045 * iavf_rx_hash - set the hash value in the skb 1046 * @ring: descriptor ring 1047 * @rx_desc: specific descriptor 1048 * @skb: skb currently being received and modified 1049 * @rx_ptype: Rx packet type 1050 **/ 1051 static inline void iavf_rx_hash(struct iavf_ring *ring, 1052 union iavf_rx_desc *rx_desc, 1053 struct sk_buff *skb, 1054 u8 rx_ptype) 1055 { 1056 u32 hash; 1057 const __le64 rss_mask = 1058 cpu_to_le64((u64)IAVF_RX_DESC_FLTSTAT_RSS_HASH << 1059 IAVF_RX_DESC_STATUS_FLTSTAT_SHIFT); 1060 1061 if (ring->netdev->features & NETIF_F_RXHASH) 1062 return; 1063 1064 if ((rx_desc->wb.qword1.status_error_len & rss_mask) == rss_mask) { 1065 hash = le32_to_cpu(rx_desc->wb.qword0.hi_dword.rss); 1066 skb_set_hash(skb, hash, iavf_ptype_to_htype(rx_ptype)); 1067 } 1068 } 1069 1070 /** 1071 * iavf_process_skb_fields - Populate skb header fields from Rx descriptor 1072 * @rx_ring: rx descriptor ring packet is being transacted on 1073 * @rx_desc: pointer to the EOP Rx descriptor 1074 * @skb: pointer to current skb being populated 1075 * @rx_ptype: the packet type decoded by hardware 1076 * 1077 * This function checks the ring, descriptor, and packet information in 1078 * order to populate the hash, checksum, VLAN, protocol, and 1079 * other fields within the skb. 1080 **/ 1081 static inline 1082 void iavf_process_skb_fields(struct iavf_ring *rx_ring, 1083 union iavf_rx_desc *rx_desc, struct sk_buff *skb, 1084 u8 rx_ptype) 1085 { 1086 iavf_rx_hash(rx_ring, rx_desc, skb, rx_ptype); 1087 1088 iavf_rx_checksum(rx_ring->vsi, skb, rx_desc); 1089 1090 skb_record_rx_queue(skb, rx_ring->queue_index); 1091 1092 /* modifies the skb - consumes the enet header */ 1093 skb->protocol = eth_type_trans(skb, rx_ring->netdev); 1094 } 1095 1096 /** 1097 * iavf_cleanup_headers - Correct empty headers 1098 * @rx_ring: rx descriptor ring packet is being transacted on 1099 * @skb: pointer to current skb being fixed 1100 * 1101 * Also address the case where we are pulling data in on pages only 1102 * and as such no data is present in the skb header. 1103 * 1104 * In addition if skb is not at least 60 bytes we need to pad it so that 1105 * it is large enough to qualify as a valid Ethernet frame. 1106 * 1107 * Returns true if an error was encountered and skb was freed. 1108 **/ 1109 static bool iavf_cleanup_headers(struct iavf_ring *rx_ring, struct sk_buff *skb) 1110 { 1111 /* if eth_skb_pad returns an error the skb was freed */ 1112 if (eth_skb_pad(skb)) 1113 return true; 1114 1115 return false; 1116 } 1117 1118 /** 1119 * iavf_reuse_rx_page - page flip buffer and store it back on the ring 1120 * @rx_ring: rx descriptor ring to store buffers on 1121 * @old_buff: donor buffer to have page reused 1122 * 1123 * Synchronizes page for reuse by the adapter 1124 **/ 1125 static void iavf_reuse_rx_page(struct iavf_ring *rx_ring, 1126 struct iavf_rx_buffer *old_buff) 1127 { 1128 struct iavf_rx_buffer *new_buff; 1129 u16 nta = rx_ring->next_to_alloc; 1130 1131 new_buff = &rx_ring->rx_bi[nta]; 1132 1133 /* update, and store next to alloc */ 1134 nta++; 1135 rx_ring->next_to_alloc = (nta < rx_ring->count) ? nta : 0; 1136 1137 /* transfer page from old buffer to new buffer */ 1138 new_buff->dma = old_buff->dma; 1139 new_buff->page = old_buff->page; 1140 new_buff->page_offset = old_buff->page_offset; 1141 new_buff->pagecnt_bias = old_buff->pagecnt_bias; 1142 } 1143 1144 /** 1145 * iavf_page_is_reusable - check if any reuse is possible 1146 * @page: page struct to check 1147 * 1148 * A page is not reusable if it was allocated under low memory 1149 * conditions, or it's not in the same NUMA node as this CPU. 1150 */ 1151 static inline bool iavf_page_is_reusable(struct page *page) 1152 { 1153 return (page_to_nid(page) == numa_mem_id()) && 1154 !page_is_pfmemalloc(page); 1155 } 1156 1157 /** 1158 * iavf_can_reuse_rx_page - Determine if this page can be reused by 1159 * the adapter for another receive 1160 * 1161 * @rx_buffer: buffer containing the page 1162 * 1163 * If page is reusable, rx_buffer->page_offset is adjusted to point to 1164 * an unused region in the page. 1165 * 1166 * For small pages, @truesize will be a constant value, half the size 1167 * of the memory at page. We'll attempt to alternate between high and 1168 * low halves of the page, with one half ready for use by the hardware 1169 * and the other half being consumed by the stack. We use the page 1170 * ref count to determine whether the stack has finished consuming the 1171 * portion of this page that was passed up with a previous packet. If 1172 * the page ref count is >1, we'll assume the "other" half page is 1173 * still busy, and this page cannot be reused. 1174 * 1175 * For larger pages, @truesize will be the actual space used by the 1176 * received packet (adjusted upward to an even multiple of the cache 1177 * line size). This will advance through the page by the amount 1178 * actually consumed by the received packets while there is still 1179 * space for a buffer. Each region of larger pages will be used at 1180 * most once, after which the page will not be reused. 1181 * 1182 * In either case, if the page is reusable its refcount is increased. 1183 **/ 1184 static bool iavf_can_reuse_rx_page(struct iavf_rx_buffer *rx_buffer) 1185 { 1186 unsigned int pagecnt_bias = rx_buffer->pagecnt_bias; 1187 struct page *page = rx_buffer->page; 1188 1189 /* Is any reuse possible? */ 1190 if (unlikely(!iavf_page_is_reusable(page))) 1191 return false; 1192 1193 #if (PAGE_SIZE < 8192) 1194 /* if we are only owner of page we can reuse it */ 1195 if (unlikely((page_count(page) - pagecnt_bias) > 1)) 1196 return false; 1197 #else 1198 #define IAVF_LAST_OFFSET \ 1199 (SKB_WITH_OVERHEAD(PAGE_SIZE) - IAVF_RXBUFFER_2048) 1200 if (rx_buffer->page_offset > IAVF_LAST_OFFSET) 1201 return false; 1202 #endif 1203 1204 /* If we have drained the page fragment pool we need to update 1205 * the pagecnt_bias and page count so that we fully restock the 1206 * number of references the driver holds. 1207 */ 1208 if (unlikely(!pagecnt_bias)) { 1209 page_ref_add(page, USHRT_MAX); 1210 rx_buffer->pagecnt_bias = USHRT_MAX; 1211 } 1212 1213 return true; 1214 } 1215 1216 /** 1217 * iavf_add_rx_frag - Add contents of Rx buffer to sk_buff 1218 * @rx_ring: rx descriptor ring to transact packets on 1219 * @rx_buffer: buffer containing page to add 1220 * @skb: sk_buff to place the data into 1221 * @size: packet length from rx_desc 1222 * 1223 * This function will add the data contained in rx_buffer->page to the skb. 1224 * It will just attach the page as a frag to the skb. 1225 * 1226 * The function will then update the page offset. 1227 **/ 1228 static void iavf_add_rx_frag(struct iavf_ring *rx_ring, 1229 struct iavf_rx_buffer *rx_buffer, 1230 struct sk_buff *skb, 1231 unsigned int size) 1232 { 1233 #if (PAGE_SIZE < 8192) 1234 unsigned int truesize = iavf_rx_pg_size(rx_ring) / 2; 1235 #else 1236 unsigned int truesize = SKB_DATA_ALIGN(size + iavf_rx_offset(rx_ring)); 1237 #endif 1238 1239 if (!size) 1240 return; 1241 1242 skb_add_rx_frag(skb, skb_shinfo(skb)->nr_frags, rx_buffer->page, 1243 rx_buffer->page_offset, size, truesize); 1244 1245 /* page is being used so we must update the page offset */ 1246 #if (PAGE_SIZE < 8192) 1247 rx_buffer->page_offset ^= truesize; 1248 #else 1249 rx_buffer->page_offset += truesize; 1250 #endif 1251 } 1252 1253 /** 1254 * iavf_get_rx_buffer - Fetch Rx buffer and synchronize data for use 1255 * @rx_ring: rx descriptor ring to transact packets on 1256 * @size: size of buffer to add to skb 1257 * 1258 * This function will pull an Rx buffer from the ring and synchronize it 1259 * for use by the CPU. 1260 */ 1261 static struct iavf_rx_buffer *iavf_get_rx_buffer(struct iavf_ring *rx_ring, 1262 const unsigned int size) 1263 { 1264 struct iavf_rx_buffer *rx_buffer; 1265 1266 if (!size) 1267 return NULL; 1268 1269 rx_buffer = &rx_ring->rx_bi[rx_ring->next_to_clean]; 1270 prefetchw(rx_buffer->page); 1271 1272 /* we are reusing so sync this buffer for CPU use */ 1273 dma_sync_single_range_for_cpu(rx_ring->dev, 1274 rx_buffer->dma, 1275 rx_buffer->page_offset, 1276 size, 1277 DMA_FROM_DEVICE); 1278 1279 /* We have pulled a buffer for use, so decrement pagecnt_bias */ 1280 rx_buffer->pagecnt_bias--; 1281 1282 return rx_buffer; 1283 } 1284 1285 /** 1286 * iavf_construct_skb - Allocate skb and populate it 1287 * @rx_ring: rx descriptor ring to transact packets on 1288 * @rx_buffer: rx buffer to pull data from 1289 * @size: size of buffer to add to skb 1290 * 1291 * This function allocates an skb. It then populates it with the page 1292 * data from the current receive descriptor, taking care to set up the 1293 * skb correctly. 1294 */ 1295 static struct sk_buff *iavf_construct_skb(struct iavf_ring *rx_ring, 1296 struct iavf_rx_buffer *rx_buffer, 1297 unsigned int size) 1298 { 1299 void *va; 1300 #if (PAGE_SIZE < 8192) 1301 unsigned int truesize = iavf_rx_pg_size(rx_ring) / 2; 1302 #else 1303 unsigned int truesize = SKB_DATA_ALIGN(size); 1304 #endif 1305 unsigned int headlen; 1306 struct sk_buff *skb; 1307 1308 if (!rx_buffer) 1309 return NULL; 1310 /* prefetch first cache line of first page */ 1311 va = page_address(rx_buffer->page) + rx_buffer->page_offset; 1312 prefetch(va); 1313 #if L1_CACHE_BYTES < 128 1314 prefetch(va + L1_CACHE_BYTES); 1315 #endif 1316 1317 /* allocate a skb to store the frags */ 1318 skb = __napi_alloc_skb(&rx_ring->q_vector->napi, 1319 IAVF_RX_HDR_SIZE, 1320 GFP_ATOMIC | __GFP_NOWARN); 1321 if (unlikely(!skb)) 1322 return NULL; 1323 1324 /* Determine available headroom for copy */ 1325 headlen = size; 1326 if (headlen > IAVF_RX_HDR_SIZE) 1327 headlen = eth_get_headlen(skb->dev, va, IAVF_RX_HDR_SIZE); 1328 1329 /* align pull length to size of long to optimize memcpy performance */ 1330 memcpy(__skb_put(skb, headlen), va, ALIGN(headlen, sizeof(long))); 1331 1332 /* update all of the pointers */ 1333 size -= headlen; 1334 if (size) { 1335 skb_add_rx_frag(skb, 0, rx_buffer->page, 1336 rx_buffer->page_offset + headlen, 1337 size, truesize); 1338 1339 /* buffer is used by skb, update page_offset */ 1340 #if (PAGE_SIZE < 8192) 1341 rx_buffer->page_offset ^= truesize; 1342 #else 1343 rx_buffer->page_offset += truesize; 1344 #endif 1345 } else { 1346 /* buffer is unused, reset bias back to rx_buffer */ 1347 rx_buffer->pagecnt_bias++; 1348 } 1349 1350 return skb; 1351 } 1352 1353 /** 1354 * iavf_build_skb - Build skb around an existing buffer 1355 * @rx_ring: Rx descriptor ring to transact packets on 1356 * @rx_buffer: Rx buffer to pull data from 1357 * @size: size of buffer to add to skb 1358 * 1359 * This function builds an skb around an existing Rx buffer, taking care 1360 * to set up the skb correctly and avoid any memcpy overhead. 1361 */ 1362 static struct sk_buff *iavf_build_skb(struct iavf_ring *rx_ring, 1363 struct iavf_rx_buffer *rx_buffer, 1364 unsigned int size) 1365 { 1366 void *va; 1367 #if (PAGE_SIZE < 8192) 1368 unsigned int truesize = iavf_rx_pg_size(rx_ring) / 2; 1369 #else 1370 unsigned int truesize = SKB_DATA_ALIGN(sizeof(struct skb_shared_info)) + 1371 SKB_DATA_ALIGN(IAVF_SKB_PAD + size); 1372 #endif 1373 struct sk_buff *skb; 1374 1375 if (!rx_buffer) 1376 return NULL; 1377 /* prefetch first cache line of first page */ 1378 va = page_address(rx_buffer->page) + rx_buffer->page_offset; 1379 prefetch(va); 1380 #if L1_CACHE_BYTES < 128 1381 prefetch(va + L1_CACHE_BYTES); 1382 #endif 1383 /* build an skb around the page buffer */ 1384 skb = build_skb(va - IAVF_SKB_PAD, truesize); 1385 if (unlikely(!skb)) 1386 return NULL; 1387 1388 /* update pointers within the skb to store the data */ 1389 skb_reserve(skb, IAVF_SKB_PAD); 1390 __skb_put(skb, size); 1391 1392 /* buffer is used by skb, update page_offset */ 1393 #if (PAGE_SIZE < 8192) 1394 rx_buffer->page_offset ^= truesize; 1395 #else 1396 rx_buffer->page_offset += truesize; 1397 #endif 1398 1399 return skb; 1400 } 1401 1402 /** 1403 * iavf_put_rx_buffer - Clean up used buffer and either recycle or free 1404 * @rx_ring: rx descriptor ring to transact packets on 1405 * @rx_buffer: rx buffer to pull data from 1406 * 1407 * This function will clean up the contents of the rx_buffer. It will 1408 * either recycle the buffer or unmap it and free the associated resources. 1409 */ 1410 static void iavf_put_rx_buffer(struct iavf_ring *rx_ring, 1411 struct iavf_rx_buffer *rx_buffer) 1412 { 1413 if (!rx_buffer) 1414 return; 1415 1416 if (iavf_can_reuse_rx_page(rx_buffer)) { 1417 /* hand second half of page back to the ring */ 1418 iavf_reuse_rx_page(rx_ring, rx_buffer); 1419 rx_ring->rx_stats.page_reuse_count++; 1420 } else { 1421 /* we are not reusing the buffer so unmap it */ 1422 dma_unmap_page_attrs(rx_ring->dev, rx_buffer->dma, 1423 iavf_rx_pg_size(rx_ring), 1424 DMA_FROM_DEVICE, IAVF_RX_DMA_ATTR); 1425 __page_frag_cache_drain(rx_buffer->page, 1426 rx_buffer->pagecnt_bias); 1427 } 1428 1429 /* clear contents of buffer_info */ 1430 rx_buffer->page = NULL; 1431 } 1432 1433 /** 1434 * iavf_is_non_eop - process handling of non-EOP buffers 1435 * @rx_ring: Rx ring being processed 1436 * @rx_desc: Rx descriptor for current buffer 1437 * @skb: Current socket buffer containing buffer in progress 1438 * 1439 * This function updates next to clean. If the buffer is an EOP buffer 1440 * this function exits returning false, otherwise it will place the 1441 * sk_buff in the next buffer to be chained and return true indicating 1442 * that this is in fact a non-EOP buffer. 1443 **/ 1444 static bool iavf_is_non_eop(struct iavf_ring *rx_ring, 1445 union iavf_rx_desc *rx_desc, 1446 struct sk_buff *skb) 1447 { 1448 u32 ntc = rx_ring->next_to_clean + 1; 1449 1450 /* fetch, update, and store next to clean */ 1451 ntc = (ntc < rx_ring->count) ? ntc : 0; 1452 rx_ring->next_to_clean = ntc; 1453 1454 prefetch(IAVF_RX_DESC(rx_ring, ntc)); 1455 1456 /* if we are the last buffer then there is nothing else to do */ 1457 #define IAVF_RXD_EOF BIT(IAVF_RX_DESC_STATUS_EOF_SHIFT) 1458 if (likely(iavf_test_staterr(rx_desc, IAVF_RXD_EOF))) 1459 return false; 1460 1461 rx_ring->rx_stats.non_eop_descs++; 1462 1463 return true; 1464 } 1465 1466 /** 1467 * iavf_clean_rx_irq - Clean completed descriptors from Rx ring - bounce buf 1468 * @rx_ring: rx descriptor ring to transact packets on 1469 * @budget: Total limit on number of packets to process 1470 * 1471 * This function provides a "bounce buffer" approach to Rx interrupt 1472 * processing. The advantage to this is that on systems that have 1473 * expensive overhead for IOMMU access this provides a means of avoiding 1474 * it by maintaining the mapping of the page to the system. 1475 * 1476 * Returns amount of work completed 1477 **/ 1478 static int iavf_clean_rx_irq(struct iavf_ring *rx_ring, int budget) 1479 { 1480 unsigned int total_rx_bytes = 0, total_rx_packets = 0; 1481 struct sk_buff *skb = rx_ring->skb; 1482 u16 cleaned_count = IAVF_DESC_UNUSED(rx_ring); 1483 bool failure = false; 1484 1485 while (likely(total_rx_packets < (unsigned int)budget)) { 1486 struct iavf_rx_buffer *rx_buffer; 1487 union iavf_rx_desc *rx_desc; 1488 unsigned int size; 1489 u16 vlan_tag; 1490 u8 rx_ptype; 1491 u64 qword; 1492 1493 /* return some buffers to hardware, one at a time is too slow */ 1494 if (cleaned_count >= IAVF_RX_BUFFER_WRITE) { 1495 failure = failure || 1496 iavf_alloc_rx_buffers(rx_ring, cleaned_count); 1497 cleaned_count = 0; 1498 } 1499 1500 rx_desc = IAVF_RX_DESC(rx_ring, rx_ring->next_to_clean); 1501 1502 /* status_error_len will always be zero for unused descriptors 1503 * because it's cleared in cleanup, and overlaps with hdr_addr 1504 * which is always zero because packet split isn't used, if the 1505 * hardware wrote DD then the length will be non-zero 1506 */ 1507 qword = le64_to_cpu(rx_desc->wb.qword1.status_error_len); 1508 1509 /* This memory barrier is needed to keep us from reading 1510 * any other fields out of the rx_desc until we have 1511 * verified the descriptor has been written back. 1512 */ 1513 dma_rmb(); 1514 #define IAVF_RXD_DD BIT(IAVF_RX_DESC_STATUS_DD_SHIFT) 1515 if (!iavf_test_staterr(rx_desc, IAVF_RXD_DD)) 1516 break; 1517 1518 size = (qword & IAVF_RXD_QW1_LENGTH_PBUF_MASK) >> 1519 IAVF_RXD_QW1_LENGTH_PBUF_SHIFT; 1520 1521 iavf_trace(clean_rx_irq, rx_ring, rx_desc, skb); 1522 rx_buffer = iavf_get_rx_buffer(rx_ring, size); 1523 1524 /* retrieve a buffer from the ring */ 1525 if (skb) 1526 iavf_add_rx_frag(rx_ring, rx_buffer, skb, size); 1527 else if (ring_uses_build_skb(rx_ring)) 1528 skb = iavf_build_skb(rx_ring, rx_buffer, size); 1529 else 1530 skb = iavf_construct_skb(rx_ring, rx_buffer, size); 1531 1532 /* exit if we failed to retrieve a buffer */ 1533 if (!skb) { 1534 rx_ring->rx_stats.alloc_buff_failed++; 1535 if (rx_buffer) 1536 rx_buffer->pagecnt_bias++; 1537 break; 1538 } 1539 1540 iavf_put_rx_buffer(rx_ring, rx_buffer); 1541 cleaned_count++; 1542 1543 if (iavf_is_non_eop(rx_ring, rx_desc, skb)) 1544 continue; 1545 1546 /* ERR_MASK will only have valid bits if EOP set, and 1547 * what we are doing here is actually checking 1548 * IAVF_RX_DESC_ERROR_RXE_SHIFT, since it is the zeroth bit in 1549 * the error field 1550 */ 1551 if (unlikely(iavf_test_staterr(rx_desc, BIT(IAVF_RXD_QW1_ERROR_SHIFT)))) { 1552 dev_kfree_skb_any(skb); 1553 skb = NULL; 1554 continue; 1555 } 1556 1557 if (iavf_cleanup_headers(rx_ring, skb)) { 1558 skb = NULL; 1559 continue; 1560 } 1561 1562 /* probably a little skewed due to removing CRC */ 1563 total_rx_bytes += skb->len; 1564 1565 qword = le64_to_cpu(rx_desc->wb.qword1.status_error_len); 1566 rx_ptype = (qword & IAVF_RXD_QW1_PTYPE_MASK) >> 1567 IAVF_RXD_QW1_PTYPE_SHIFT; 1568 1569 /* populate checksum, VLAN, and protocol */ 1570 iavf_process_skb_fields(rx_ring, rx_desc, skb, rx_ptype); 1571 1572 1573 vlan_tag = (qword & BIT(IAVF_RX_DESC_STATUS_L2TAG1P_SHIFT)) ? 1574 le16_to_cpu(rx_desc->wb.qword0.lo_dword.l2tag1) : 0; 1575 1576 iavf_trace(clean_rx_irq_rx, rx_ring, rx_desc, skb); 1577 iavf_receive_skb(rx_ring, skb, vlan_tag); 1578 skb = NULL; 1579 1580 /* update budget accounting */ 1581 total_rx_packets++; 1582 } 1583 1584 rx_ring->skb = skb; 1585 1586 u64_stats_update_begin(&rx_ring->syncp); 1587 rx_ring->stats.packets += total_rx_packets; 1588 rx_ring->stats.bytes += total_rx_bytes; 1589 u64_stats_update_end(&rx_ring->syncp); 1590 rx_ring->q_vector->rx.total_packets += total_rx_packets; 1591 rx_ring->q_vector->rx.total_bytes += total_rx_bytes; 1592 1593 /* guarantee a trip back through this routine if there was a failure */ 1594 return failure ? budget : (int)total_rx_packets; 1595 } 1596 1597 static inline u32 iavf_buildreg_itr(const int type, u16 itr) 1598 { 1599 u32 val; 1600 1601 /* We don't bother with setting the CLEARPBA bit as the data sheet 1602 * points out doing so is "meaningless since it was already 1603 * auto-cleared". The auto-clearing happens when the interrupt is 1604 * asserted. 1605 * 1606 * Hardware errata 28 for also indicates that writing to a 1607 * xxINT_DYN_CTLx CSR with INTENA_MSK (bit 31) set to 0 will clear 1608 * an event in the PBA anyway so we need to rely on the automask 1609 * to hold pending events for us until the interrupt is re-enabled 1610 * 1611 * The itr value is reported in microseconds, and the register 1612 * value is recorded in 2 microsecond units. For this reason we 1613 * only need to shift by the interval shift - 1 instead of the 1614 * full value. 1615 */ 1616 itr &= IAVF_ITR_MASK; 1617 1618 val = IAVF_VFINT_DYN_CTLN1_INTENA_MASK | 1619 (type << IAVF_VFINT_DYN_CTLN1_ITR_INDX_SHIFT) | 1620 (itr << (IAVF_VFINT_DYN_CTLN1_INTERVAL_SHIFT - 1)); 1621 1622 return val; 1623 } 1624 1625 /* a small macro to shorten up some long lines */ 1626 #define INTREG IAVF_VFINT_DYN_CTLN1 1627 1628 /* The act of updating the ITR will cause it to immediately trigger. In order 1629 * to prevent this from throwing off adaptive update statistics we defer the 1630 * update so that it can only happen so often. So after either Tx or Rx are 1631 * updated we make the adaptive scheme wait until either the ITR completely 1632 * expires via the next_update expiration or we have been through at least 1633 * 3 interrupts. 1634 */ 1635 #define ITR_COUNTDOWN_START 3 1636 1637 /** 1638 * iavf_update_enable_itr - Update itr and re-enable MSIX interrupt 1639 * @vsi: the VSI we care about 1640 * @q_vector: q_vector for which itr is being updated and interrupt enabled 1641 * 1642 **/ 1643 static inline void iavf_update_enable_itr(struct iavf_vsi *vsi, 1644 struct iavf_q_vector *q_vector) 1645 { 1646 struct iavf_hw *hw = &vsi->back->hw; 1647 u32 intval; 1648 1649 /* These will do nothing if dynamic updates are not enabled */ 1650 iavf_update_itr(q_vector, &q_vector->tx); 1651 iavf_update_itr(q_vector, &q_vector->rx); 1652 1653 /* This block of logic allows us to get away with only updating 1654 * one ITR value with each interrupt. The idea is to perform a 1655 * pseudo-lazy update with the following criteria. 1656 * 1657 * 1. Rx is given higher priority than Tx if both are in same state 1658 * 2. If we must reduce an ITR that is given highest priority. 1659 * 3. We then give priority to increasing ITR based on amount. 1660 */ 1661 if (q_vector->rx.target_itr < q_vector->rx.current_itr) { 1662 /* Rx ITR needs to be reduced, this is highest priority */ 1663 intval = iavf_buildreg_itr(IAVF_RX_ITR, 1664 q_vector->rx.target_itr); 1665 q_vector->rx.current_itr = q_vector->rx.target_itr; 1666 q_vector->itr_countdown = ITR_COUNTDOWN_START; 1667 } else if ((q_vector->tx.target_itr < q_vector->tx.current_itr) || 1668 ((q_vector->rx.target_itr - q_vector->rx.current_itr) < 1669 (q_vector->tx.target_itr - q_vector->tx.current_itr))) { 1670 /* Tx ITR needs to be reduced, this is second priority 1671 * Tx ITR needs to be increased more than Rx, fourth priority 1672 */ 1673 intval = iavf_buildreg_itr(IAVF_TX_ITR, 1674 q_vector->tx.target_itr); 1675 q_vector->tx.current_itr = q_vector->tx.target_itr; 1676 q_vector->itr_countdown = ITR_COUNTDOWN_START; 1677 } else if (q_vector->rx.current_itr != q_vector->rx.target_itr) { 1678 /* Rx ITR needs to be increased, third priority */ 1679 intval = iavf_buildreg_itr(IAVF_RX_ITR, 1680 q_vector->rx.target_itr); 1681 q_vector->rx.current_itr = q_vector->rx.target_itr; 1682 q_vector->itr_countdown = ITR_COUNTDOWN_START; 1683 } else { 1684 /* No ITR update, lowest priority */ 1685 intval = iavf_buildreg_itr(IAVF_ITR_NONE, 0); 1686 if (q_vector->itr_countdown) 1687 q_vector->itr_countdown--; 1688 } 1689 1690 if (!test_bit(__IAVF_VSI_DOWN, vsi->state)) 1691 wr32(hw, INTREG(q_vector->reg_idx), intval); 1692 } 1693 1694 /** 1695 * iavf_napi_poll - NAPI polling Rx/Tx cleanup routine 1696 * @napi: napi struct with our devices info in it 1697 * @budget: amount of work driver is allowed to do this pass, in packets 1698 * 1699 * This function will clean all queues associated with a q_vector. 1700 * 1701 * Returns the amount of work done 1702 **/ 1703 int iavf_napi_poll(struct napi_struct *napi, int budget) 1704 { 1705 struct iavf_q_vector *q_vector = 1706 container_of(napi, struct iavf_q_vector, napi); 1707 struct iavf_vsi *vsi = q_vector->vsi; 1708 struct iavf_ring *ring; 1709 bool clean_complete = true; 1710 bool arm_wb = false; 1711 int budget_per_ring; 1712 int work_done = 0; 1713 1714 if (test_bit(__IAVF_VSI_DOWN, vsi->state)) { 1715 napi_complete(napi); 1716 return 0; 1717 } 1718 1719 /* Since the actual Tx work is minimal, we can give the Tx a larger 1720 * budget and be more aggressive about cleaning up the Tx descriptors. 1721 */ 1722 iavf_for_each_ring(ring, q_vector->tx) { 1723 if (!iavf_clean_tx_irq(vsi, ring, budget)) { 1724 clean_complete = false; 1725 continue; 1726 } 1727 arm_wb |= ring->arm_wb; 1728 ring->arm_wb = false; 1729 } 1730 1731 /* Handle case where we are called by netpoll with a budget of 0 */ 1732 if (budget <= 0) 1733 goto tx_only; 1734 1735 /* We attempt to distribute budget to each Rx queue fairly, but don't 1736 * allow the budget to go below 1 because that would exit polling early. 1737 */ 1738 budget_per_ring = max(budget/q_vector->num_ringpairs, 1); 1739 1740 iavf_for_each_ring(ring, q_vector->rx) { 1741 int cleaned = iavf_clean_rx_irq(ring, budget_per_ring); 1742 1743 work_done += cleaned; 1744 /* if we clean as many as budgeted, we must not be done */ 1745 if (cleaned >= budget_per_ring) 1746 clean_complete = false; 1747 } 1748 1749 /* If work not completed, return budget and polling will return */ 1750 if (!clean_complete) { 1751 int cpu_id = smp_processor_id(); 1752 1753 /* It is possible that the interrupt affinity has changed but, 1754 * if the cpu is pegged at 100%, polling will never exit while 1755 * traffic continues and the interrupt will be stuck on this 1756 * cpu. We check to make sure affinity is correct before we 1757 * continue to poll, otherwise we must stop polling so the 1758 * interrupt can move to the correct cpu. 1759 */ 1760 if (!cpumask_test_cpu(cpu_id, &q_vector->affinity_mask)) { 1761 /* Tell napi that we are done polling */ 1762 napi_complete_done(napi, work_done); 1763 1764 /* Force an interrupt */ 1765 iavf_force_wb(vsi, q_vector); 1766 1767 /* Return budget-1 so that polling stops */ 1768 return budget - 1; 1769 } 1770 tx_only: 1771 if (arm_wb) { 1772 q_vector->tx.ring[0].tx_stats.tx_force_wb++; 1773 iavf_enable_wb_on_itr(vsi, q_vector); 1774 } 1775 return budget; 1776 } 1777 1778 if (vsi->back->flags & IAVF_TXR_FLAGS_WB_ON_ITR) 1779 q_vector->arm_wb_state = false; 1780 1781 /* Exit the polling mode, but don't re-enable interrupts if stack might 1782 * poll us due to busy-polling 1783 */ 1784 if (likely(napi_complete_done(napi, work_done))) 1785 iavf_update_enable_itr(vsi, q_vector); 1786 1787 return min(work_done, budget - 1); 1788 } 1789 1790 /** 1791 * iavf_tx_prepare_vlan_flags - prepare generic TX VLAN tagging flags for HW 1792 * @skb: send buffer 1793 * @tx_ring: ring to send buffer on 1794 * @flags: the tx flags to be set 1795 * 1796 * Checks the skb and set up correspondingly several generic transmit flags 1797 * related to VLAN tagging for the HW, such as VLAN, DCB, etc. 1798 * 1799 * Returns error code indicate the frame should be dropped upon error and the 1800 * otherwise returns 0 to indicate the flags has been set properly. 1801 **/ 1802 static inline int iavf_tx_prepare_vlan_flags(struct sk_buff *skb, 1803 struct iavf_ring *tx_ring, 1804 u32 *flags) 1805 { 1806 __be16 protocol = skb->protocol; 1807 u32 tx_flags = 0; 1808 1809 if (protocol == htons(ETH_P_8021Q) && 1810 !(tx_ring->netdev->features & NETIF_F_HW_VLAN_CTAG_TX)) { 1811 /* When HW VLAN acceleration is turned off by the user the 1812 * stack sets the protocol to 8021q so that the driver 1813 * can take any steps required to support the SW only 1814 * VLAN handling. In our case the driver doesn't need 1815 * to take any further steps so just set the protocol 1816 * to the encapsulated ethertype. 1817 */ 1818 skb->protocol = vlan_get_protocol(skb); 1819 goto out; 1820 } 1821 1822 /* if we have a HW VLAN tag being added, default to the HW one */ 1823 if (skb_vlan_tag_present(skb)) { 1824 tx_flags |= skb_vlan_tag_get(skb) << IAVF_TX_FLAGS_VLAN_SHIFT; 1825 tx_flags |= IAVF_TX_FLAGS_HW_VLAN; 1826 /* else if it is a SW VLAN, check the next protocol and store the tag */ 1827 } else if (protocol == htons(ETH_P_8021Q)) { 1828 struct vlan_hdr *vhdr, _vhdr; 1829 1830 vhdr = skb_header_pointer(skb, ETH_HLEN, sizeof(_vhdr), &_vhdr); 1831 if (!vhdr) 1832 return -EINVAL; 1833 1834 protocol = vhdr->h_vlan_encapsulated_proto; 1835 tx_flags |= ntohs(vhdr->h_vlan_TCI) << IAVF_TX_FLAGS_VLAN_SHIFT; 1836 tx_flags |= IAVF_TX_FLAGS_SW_VLAN; 1837 } 1838 1839 out: 1840 *flags = tx_flags; 1841 return 0; 1842 } 1843 1844 /** 1845 * iavf_tso - set up the tso context descriptor 1846 * @first: pointer to first Tx buffer for xmit 1847 * @hdr_len: ptr to the size of the packet header 1848 * @cd_type_cmd_tso_mss: Quad Word 1 1849 * 1850 * Returns 0 if no TSO can happen, 1 if tso is going, or error 1851 **/ 1852 static int iavf_tso(struct iavf_tx_buffer *first, u8 *hdr_len, 1853 u64 *cd_type_cmd_tso_mss) 1854 { 1855 struct sk_buff *skb = first->skb; 1856 u64 cd_cmd, cd_tso_len, cd_mss; 1857 union { 1858 struct iphdr *v4; 1859 struct ipv6hdr *v6; 1860 unsigned char *hdr; 1861 } ip; 1862 union { 1863 struct tcphdr *tcp; 1864 struct udphdr *udp; 1865 unsigned char *hdr; 1866 } l4; 1867 u32 paylen, l4_offset; 1868 u16 gso_segs, gso_size; 1869 int err; 1870 1871 if (skb->ip_summed != CHECKSUM_PARTIAL) 1872 return 0; 1873 1874 if (!skb_is_gso(skb)) 1875 return 0; 1876 1877 err = skb_cow_head(skb, 0); 1878 if (err < 0) 1879 return err; 1880 1881 ip.hdr = skb_network_header(skb); 1882 l4.hdr = skb_transport_header(skb); 1883 1884 /* initialize outer IP header fields */ 1885 if (ip.v4->version == 4) { 1886 ip.v4->tot_len = 0; 1887 ip.v4->check = 0; 1888 } else { 1889 ip.v6->payload_len = 0; 1890 } 1891 1892 if (skb_shinfo(skb)->gso_type & (SKB_GSO_GRE | 1893 SKB_GSO_GRE_CSUM | 1894 SKB_GSO_IPXIP4 | 1895 SKB_GSO_IPXIP6 | 1896 SKB_GSO_UDP_TUNNEL | 1897 SKB_GSO_UDP_TUNNEL_CSUM)) { 1898 if (!(skb_shinfo(skb)->gso_type & SKB_GSO_PARTIAL) && 1899 (skb_shinfo(skb)->gso_type & SKB_GSO_UDP_TUNNEL_CSUM)) { 1900 l4.udp->len = 0; 1901 1902 /* determine offset of outer transport header */ 1903 l4_offset = l4.hdr - skb->data; 1904 1905 /* remove payload length from outer checksum */ 1906 paylen = skb->len - l4_offset; 1907 csum_replace_by_diff(&l4.udp->check, 1908 (__force __wsum)htonl(paylen)); 1909 } 1910 1911 /* reset pointers to inner headers */ 1912 ip.hdr = skb_inner_network_header(skb); 1913 l4.hdr = skb_inner_transport_header(skb); 1914 1915 /* initialize inner IP header fields */ 1916 if (ip.v4->version == 4) { 1917 ip.v4->tot_len = 0; 1918 ip.v4->check = 0; 1919 } else { 1920 ip.v6->payload_len = 0; 1921 } 1922 } 1923 1924 /* determine offset of inner transport header */ 1925 l4_offset = l4.hdr - skb->data; 1926 1927 /* remove payload length from inner checksum */ 1928 paylen = skb->len - l4_offset; 1929 csum_replace_by_diff(&l4.tcp->check, (__force __wsum)htonl(paylen)); 1930 1931 /* compute length of segmentation header */ 1932 *hdr_len = (l4.tcp->doff * 4) + l4_offset; 1933 1934 /* pull values out of skb_shinfo */ 1935 gso_size = skb_shinfo(skb)->gso_size; 1936 gso_segs = skb_shinfo(skb)->gso_segs; 1937 1938 /* update GSO size and bytecount with header size */ 1939 first->gso_segs = gso_segs; 1940 first->bytecount += (first->gso_segs - 1) * *hdr_len; 1941 1942 /* find the field values */ 1943 cd_cmd = IAVF_TX_CTX_DESC_TSO; 1944 cd_tso_len = skb->len - *hdr_len; 1945 cd_mss = gso_size; 1946 *cd_type_cmd_tso_mss |= (cd_cmd << IAVF_TXD_CTX_QW1_CMD_SHIFT) | 1947 (cd_tso_len << IAVF_TXD_CTX_QW1_TSO_LEN_SHIFT) | 1948 (cd_mss << IAVF_TXD_CTX_QW1_MSS_SHIFT); 1949 return 1; 1950 } 1951 1952 /** 1953 * iavf_tx_enable_csum - Enable Tx checksum offloads 1954 * @skb: send buffer 1955 * @tx_flags: pointer to Tx flags currently set 1956 * @td_cmd: Tx descriptor command bits to set 1957 * @td_offset: Tx descriptor header offsets to set 1958 * @tx_ring: Tx descriptor ring 1959 * @cd_tunneling: ptr to context desc bits 1960 **/ 1961 static int iavf_tx_enable_csum(struct sk_buff *skb, u32 *tx_flags, 1962 u32 *td_cmd, u32 *td_offset, 1963 struct iavf_ring *tx_ring, 1964 u32 *cd_tunneling) 1965 { 1966 union { 1967 struct iphdr *v4; 1968 struct ipv6hdr *v6; 1969 unsigned char *hdr; 1970 } ip; 1971 union { 1972 struct tcphdr *tcp; 1973 struct udphdr *udp; 1974 unsigned char *hdr; 1975 } l4; 1976 unsigned char *exthdr; 1977 u32 offset, cmd = 0; 1978 __be16 frag_off; 1979 u8 l4_proto = 0; 1980 1981 if (skb->ip_summed != CHECKSUM_PARTIAL) 1982 return 0; 1983 1984 ip.hdr = skb_network_header(skb); 1985 l4.hdr = skb_transport_header(skb); 1986 1987 /* compute outer L2 header size */ 1988 offset = ((ip.hdr - skb->data) / 2) << IAVF_TX_DESC_LENGTH_MACLEN_SHIFT; 1989 1990 if (skb->encapsulation) { 1991 u32 tunnel = 0; 1992 /* define outer network header type */ 1993 if (*tx_flags & IAVF_TX_FLAGS_IPV4) { 1994 tunnel |= (*tx_flags & IAVF_TX_FLAGS_TSO) ? 1995 IAVF_TX_CTX_EXT_IP_IPV4 : 1996 IAVF_TX_CTX_EXT_IP_IPV4_NO_CSUM; 1997 1998 l4_proto = ip.v4->protocol; 1999 } else if (*tx_flags & IAVF_TX_FLAGS_IPV6) { 2000 tunnel |= IAVF_TX_CTX_EXT_IP_IPV6; 2001 2002 exthdr = ip.hdr + sizeof(*ip.v6); 2003 l4_proto = ip.v6->nexthdr; 2004 if (l4.hdr != exthdr) 2005 ipv6_skip_exthdr(skb, exthdr - skb->data, 2006 &l4_proto, &frag_off); 2007 } 2008 2009 /* define outer transport */ 2010 switch (l4_proto) { 2011 case IPPROTO_UDP: 2012 tunnel |= IAVF_TXD_CTX_UDP_TUNNELING; 2013 *tx_flags |= IAVF_TX_FLAGS_VXLAN_TUNNEL; 2014 break; 2015 case IPPROTO_GRE: 2016 tunnel |= IAVF_TXD_CTX_GRE_TUNNELING; 2017 *tx_flags |= IAVF_TX_FLAGS_VXLAN_TUNNEL; 2018 break; 2019 case IPPROTO_IPIP: 2020 case IPPROTO_IPV6: 2021 *tx_flags |= IAVF_TX_FLAGS_VXLAN_TUNNEL; 2022 l4.hdr = skb_inner_network_header(skb); 2023 break; 2024 default: 2025 if (*tx_flags & IAVF_TX_FLAGS_TSO) 2026 return -1; 2027 2028 skb_checksum_help(skb); 2029 return 0; 2030 } 2031 2032 /* compute outer L3 header size */ 2033 tunnel |= ((l4.hdr - ip.hdr) / 4) << 2034 IAVF_TXD_CTX_QW0_EXT_IPLEN_SHIFT; 2035 2036 /* switch IP header pointer from outer to inner header */ 2037 ip.hdr = skb_inner_network_header(skb); 2038 2039 /* compute tunnel header size */ 2040 tunnel |= ((ip.hdr - l4.hdr) / 2) << 2041 IAVF_TXD_CTX_QW0_NATLEN_SHIFT; 2042 2043 /* indicate if we need to offload outer UDP header */ 2044 if ((*tx_flags & IAVF_TX_FLAGS_TSO) && 2045 !(skb_shinfo(skb)->gso_type & SKB_GSO_PARTIAL) && 2046 (skb_shinfo(skb)->gso_type & SKB_GSO_UDP_TUNNEL_CSUM)) 2047 tunnel |= IAVF_TXD_CTX_QW0_L4T_CS_MASK; 2048 2049 /* record tunnel offload values */ 2050 *cd_tunneling |= tunnel; 2051 2052 /* switch L4 header pointer from outer to inner */ 2053 l4.hdr = skb_inner_transport_header(skb); 2054 l4_proto = 0; 2055 2056 /* reset type as we transition from outer to inner headers */ 2057 *tx_flags &= ~(IAVF_TX_FLAGS_IPV4 | IAVF_TX_FLAGS_IPV6); 2058 if (ip.v4->version == 4) 2059 *tx_flags |= IAVF_TX_FLAGS_IPV4; 2060 if (ip.v6->version == 6) 2061 *tx_flags |= IAVF_TX_FLAGS_IPV6; 2062 } 2063 2064 /* Enable IP checksum offloads */ 2065 if (*tx_flags & IAVF_TX_FLAGS_IPV4) { 2066 l4_proto = ip.v4->protocol; 2067 /* the stack computes the IP header already, the only time we 2068 * need the hardware to recompute it is in the case of TSO. 2069 */ 2070 cmd |= (*tx_flags & IAVF_TX_FLAGS_TSO) ? 2071 IAVF_TX_DESC_CMD_IIPT_IPV4_CSUM : 2072 IAVF_TX_DESC_CMD_IIPT_IPV4; 2073 } else if (*tx_flags & IAVF_TX_FLAGS_IPV6) { 2074 cmd |= IAVF_TX_DESC_CMD_IIPT_IPV6; 2075 2076 exthdr = ip.hdr + sizeof(*ip.v6); 2077 l4_proto = ip.v6->nexthdr; 2078 if (l4.hdr != exthdr) 2079 ipv6_skip_exthdr(skb, exthdr - skb->data, 2080 &l4_proto, &frag_off); 2081 } 2082 2083 /* compute inner L3 header size */ 2084 offset |= ((l4.hdr - ip.hdr) / 4) << IAVF_TX_DESC_LENGTH_IPLEN_SHIFT; 2085 2086 /* Enable L4 checksum offloads */ 2087 switch (l4_proto) { 2088 case IPPROTO_TCP: 2089 /* enable checksum offloads */ 2090 cmd |= IAVF_TX_DESC_CMD_L4T_EOFT_TCP; 2091 offset |= l4.tcp->doff << IAVF_TX_DESC_LENGTH_L4_FC_LEN_SHIFT; 2092 break; 2093 case IPPROTO_SCTP: 2094 /* enable SCTP checksum offload */ 2095 cmd |= IAVF_TX_DESC_CMD_L4T_EOFT_SCTP; 2096 offset |= (sizeof(struct sctphdr) >> 2) << 2097 IAVF_TX_DESC_LENGTH_L4_FC_LEN_SHIFT; 2098 break; 2099 case IPPROTO_UDP: 2100 /* enable UDP checksum offload */ 2101 cmd |= IAVF_TX_DESC_CMD_L4T_EOFT_UDP; 2102 offset |= (sizeof(struct udphdr) >> 2) << 2103 IAVF_TX_DESC_LENGTH_L4_FC_LEN_SHIFT; 2104 break; 2105 default: 2106 if (*tx_flags & IAVF_TX_FLAGS_TSO) 2107 return -1; 2108 skb_checksum_help(skb); 2109 return 0; 2110 } 2111 2112 *td_cmd |= cmd; 2113 *td_offset |= offset; 2114 2115 return 1; 2116 } 2117 2118 /** 2119 * iavf_create_tx_ctx Build the Tx context descriptor 2120 * @tx_ring: ring to create the descriptor on 2121 * @cd_type_cmd_tso_mss: Quad Word 1 2122 * @cd_tunneling: Quad Word 0 - bits 0-31 2123 * @cd_l2tag2: Quad Word 0 - bits 32-63 2124 **/ 2125 static void iavf_create_tx_ctx(struct iavf_ring *tx_ring, 2126 const u64 cd_type_cmd_tso_mss, 2127 const u32 cd_tunneling, const u32 cd_l2tag2) 2128 { 2129 struct iavf_tx_context_desc *context_desc; 2130 int i = tx_ring->next_to_use; 2131 2132 if ((cd_type_cmd_tso_mss == IAVF_TX_DESC_DTYPE_CONTEXT) && 2133 !cd_tunneling && !cd_l2tag2) 2134 return; 2135 2136 /* grab the next descriptor */ 2137 context_desc = IAVF_TX_CTXTDESC(tx_ring, i); 2138 2139 i++; 2140 tx_ring->next_to_use = (i < tx_ring->count) ? i : 0; 2141 2142 /* cpu_to_le32 and assign to struct fields */ 2143 context_desc->tunneling_params = cpu_to_le32(cd_tunneling); 2144 context_desc->l2tag2 = cpu_to_le16(cd_l2tag2); 2145 context_desc->rsvd = cpu_to_le16(0); 2146 context_desc->type_cmd_tso_mss = cpu_to_le64(cd_type_cmd_tso_mss); 2147 } 2148 2149 /** 2150 * __iavf_chk_linearize - Check if there are more than 8 buffers per packet 2151 * @skb: send buffer 2152 * 2153 * Note: Our HW can't DMA more than 8 buffers to build a packet on the wire 2154 * and so we need to figure out the cases where we need to linearize the skb. 2155 * 2156 * For TSO we need to count the TSO header and segment payload separately. 2157 * As such we need to check cases where we have 7 fragments or more as we 2158 * can potentially require 9 DMA transactions, 1 for the TSO header, 1 for 2159 * the segment payload in the first descriptor, and another 7 for the 2160 * fragments. 2161 **/ 2162 bool __iavf_chk_linearize(struct sk_buff *skb) 2163 { 2164 const skb_frag_t *frag, *stale; 2165 int nr_frags, sum; 2166 2167 /* no need to check if number of frags is less than 7 */ 2168 nr_frags = skb_shinfo(skb)->nr_frags; 2169 if (nr_frags < (IAVF_MAX_BUFFER_TXD - 1)) 2170 return false; 2171 2172 /* We need to walk through the list and validate that each group 2173 * of 6 fragments totals at least gso_size. 2174 */ 2175 nr_frags -= IAVF_MAX_BUFFER_TXD - 2; 2176 frag = &skb_shinfo(skb)->frags[0]; 2177 2178 /* Initialize size to the negative value of gso_size minus 1. We 2179 * use this as the worst case scenerio in which the frag ahead 2180 * of us only provides one byte which is why we are limited to 6 2181 * descriptors for a single transmit as the header and previous 2182 * fragment are already consuming 2 descriptors. 2183 */ 2184 sum = 1 - skb_shinfo(skb)->gso_size; 2185 2186 /* Add size of frags 0 through 4 to create our initial sum */ 2187 sum += skb_frag_size(frag++); 2188 sum += skb_frag_size(frag++); 2189 sum += skb_frag_size(frag++); 2190 sum += skb_frag_size(frag++); 2191 sum += skb_frag_size(frag++); 2192 2193 /* Walk through fragments adding latest fragment, testing it, and 2194 * then removing stale fragments from the sum. 2195 */ 2196 for (stale = &skb_shinfo(skb)->frags[0];; stale++) { 2197 int stale_size = skb_frag_size(stale); 2198 2199 sum += skb_frag_size(frag++); 2200 2201 /* The stale fragment may present us with a smaller 2202 * descriptor than the actual fragment size. To account 2203 * for that we need to remove all the data on the front and 2204 * figure out what the remainder would be in the last 2205 * descriptor associated with the fragment. 2206 */ 2207 if (stale_size > IAVF_MAX_DATA_PER_TXD) { 2208 int align_pad = -(skb_frag_off(stale)) & 2209 (IAVF_MAX_READ_REQ_SIZE - 1); 2210 2211 sum -= align_pad; 2212 stale_size -= align_pad; 2213 2214 do { 2215 sum -= IAVF_MAX_DATA_PER_TXD_ALIGNED; 2216 stale_size -= IAVF_MAX_DATA_PER_TXD_ALIGNED; 2217 } while (stale_size > IAVF_MAX_DATA_PER_TXD); 2218 } 2219 2220 /* if sum is negative we failed to make sufficient progress */ 2221 if (sum < 0) 2222 return true; 2223 2224 if (!nr_frags--) 2225 break; 2226 2227 sum -= stale_size; 2228 } 2229 2230 return false; 2231 } 2232 2233 /** 2234 * __iavf_maybe_stop_tx - 2nd level check for tx stop conditions 2235 * @tx_ring: the ring to be checked 2236 * @size: the size buffer we want to assure is available 2237 * 2238 * Returns -EBUSY if a stop is needed, else 0 2239 **/ 2240 int __iavf_maybe_stop_tx(struct iavf_ring *tx_ring, int size) 2241 { 2242 netif_stop_subqueue(tx_ring->netdev, tx_ring->queue_index); 2243 /* Memory barrier before checking head and tail */ 2244 smp_mb(); 2245 2246 /* Check again in a case another CPU has just made room available. */ 2247 if (likely(IAVF_DESC_UNUSED(tx_ring) < size)) 2248 return -EBUSY; 2249 2250 /* A reprieve! - use start_queue because it doesn't call schedule */ 2251 netif_start_subqueue(tx_ring->netdev, tx_ring->queue_index); 2252 ++tx_ring->tx_stats.restart_queue; 2253 return 0; 2254 } 2255 2256 /** 2257 * iavf_tx_map - Build the Tx descriptor 2258 * @tx_ring: ring to send buffer on 2259 * @skb: send buffer 2260 * @first: first buffer info buffer to use 2261 * @tx_flags: collected send information 2262 * @hdr_len: size of the packet header 2263 * @td_cmd: the command field in the descriptor 2264 * @td_offset: offset for checksum or crc 2265 **/ 2266 static inline void iavf_tx_map(struct iavf_ring *tx_ring, struct sk_buff *skb, 2267 struct iavf_tx_buffer *first, u32 tx_flags, 2268 const u8 hdr_len, u32 td_cmd, u32 td_offset) 2269 { 2270 unsigned int data_len = skb->data_len; 2271 unsigned int size = skb_headlen(skb); 2272 skb_frag_t *frag; 2273 struct iavf_tx_buffer *tx_bi; 2274 struct iavf_tx_desc *tx_desc; 2275 u16 i = tx_ring->next_to_use; 2276 u32 td_tag = 0; 2277 dma_addr_t dma; 2278 2279 if (tx_flags & IAVF_TX_FLAGS_HW_VLAN) { 2280 td_cmd |= IAVF_TX_DESC_CMD_IL2TAG1; 2281 td_tag = (tx_flags & IAVF_TX_FLAGS_VLAN_MASK) >> 2282 IAVF_TX_FLAGS_VLAN_SHIFT; 2283 } 2284 2285 first->tx_flags = tx_flags; 2286 2287 dma = dma_map_single(tx_ring->dev, skb->data, size, DMA_TO_DEVICE); 2288 2289 tx_desc = IAVF_TX_DESC(tx_ring, i); 2290 tx_bi = first; 2291 2292 for (frag = &skb_shinfo(skb)->frags[0];; frag++) { 2293 unsigned int max_data = IAVF_MAX_DATA_PER_TXD_ALIGNED; 2294 2295 if (dma_mapping_error(tx_ring->dev, dma)) 2296 goto dma_error; 2297 2298 /* record length, and DMA address */ 2299 dma_unmap_len_set(tx_bi, len, size); 2300 dma_unmap_addr_set(tx_bi, dma, dma); 2301 2302 /* align size to end of page */ 2303 max_data += -dma & (IAVF_MAX_READ_REQ_SIZE - 1); 2304 tx_desc->buffer_addr = cpu_to_le64(dma); 2305 2306 while (unlikely(size > IAVF_MAX_DATA_PER_TXD)) { 2307 tx_desc->cmd_type_offset_bsz = 2308 build_ctob(td_cmd, td_offset, 2309 max_data, td_tag); 2310 2311 tx_desc++; 2312 i++; 2313 2314 if (i == tx_ring->count) { 2315 tx_desc = IAVF_TX_DESC(tx_ring, 0); 2316 i = 0; 2317 } 2318 2319 dma += max_data; 2320 size -= max_data; 2321 2322 max_data = IAVF_MAX_DATA_PER_TXD_ALIGNED; 2323 tx_desc->buffer_addr = cpu_to_le64(dma); 2324 } 2325 2326 if (likely(!data_len)) 2327 break; 2328 2329 tx_desc->cmd_type_offset_bsz = build_ctob(td_cmd, td_offset, 2330 size, td_tag); 2331 2332 tx_desc++; 2333 i++; 2334 2335 if (i == tx_ring->count) { 2336 tx_desc = IAVF_TX_DESC(tx_ring, 0); 2337 i = 0; 2338 } 2339 2340 size = skb_frag_size(frag); 2341 data_len -= size; 2342 2343 dma = skb_frag_dma_map(tx_ring->dev, frag, 0, size, 2344 DMA_TO_DEVICE); 2345 2346 tx_bi = &tx_ring->tx_bi[i]; 2347 } 2348 2349 netdev_tx_sent_queue(txring_txq(tx_ring), first->bytecount); 2350 2351 i++; 2352 if (i == tx_ring->count) 2353 i = 0; 2354 2355 tx_ring->next_to_use = i; 2356 2357 iavf_maybe_stop_tx(tx_ring, DESC_NEEDED); 2358 2359 /* write last descriptor with RS and EOP bits */ 2360 td_cmd |= IAVF_TXD_CMD; 2361 tx_desc->cmd_type_offset_bsz = 2362 build_ctob(td_cmd, td_offset, size, td_tag); 2363 2364 skb_tx_timestamp(skb); 2365 2366 /* Force memory writes to complete before letting h/w know there 2367 * are new descriptors to fetch. 2368 * 2369 * We also use this memory barrier to make certain all of the 2370 * status bits have been updated before next_to_watch is written. 2371 */ 2372 wmb(); 2373 2374 /* set next_to_watch value indicating a packet is present */ 2375 first->next_to_watch = tx_desc; 2376 2377 /* notify HW of packet */ 2378 if (netif_xmit_stopped(txring_txq(tx_ring)) || !netdev_xmit_more()) { 2379 writel(i, tx_ring->tail); 2380 } 2381 2382 return; 2383 2384 dma_error: 2385 dev_info(tx_ring->dev, "TX DMA map failed\n"); 2386 2387 /* clear dma mappings for failed tx_bi map */ 2388 for (;;) { 2389 tx_bi = &tx_ring->tx_bi[i]; 2390 iavf_unmap_and_free_tx_resource(tx_ring, tx_bi); 2391 if (tx_bi == first) 2392 break; 2393 if (i == 0) 2394 i = tx_ring->count; 2395 i--; 2396 } 2397 2398 tx_ring->next_to_use = i; 2399 } 2400 2401 /** 2402 * iavf_xmit_frame_ring - Sends buffer on Tx ring 2403 * @skb: send buffer 2404 * @tx_ring: ring to send buffer on 2405 * 2406 * Returns NETDEV_TX_OK if sent, else an error code 2407 **/ 2408 static netdev_tx_t iavf_xmit_frame_ring(struct sk_buff *skb, 2409 struct iavf_ring *tx_ring) 2410 { 2411 u64 cd_type_cmd_tso_mss = IAVF_TX_DESC_DTYPE_CONTEXT; 2412 u32 cd_tunneling = 0, cd_l2tag2 = 0; 2413 struct iavf_tx_buffer *first; 2414 u32 td_offset = 0; 2415 u32 tx_flags = 0; 2416 __be16 protocol; 2417 u32 td_cmd = 0; 2418 u8 hdr_len = 0; 2419 int tso, count; 2420 2421 /* prefetch the data, we'll need it later */ 2422 prefetch(skb->data); 2423 2424 iavf_trace(xmit_frame_ring, skb, tx_ring); 2425 2426 count = iavf_xmit_descriptor_count(skb); 2427 if (iavf_chk_linearize(skb, count)) { 2428 if (__skb_linearize(skb)) { 2429 dev_kfree_skb_any(skb); 2430 return NETDEV_TX_OK; 2431 } 2432 count = iavf_txd_use_count(skb->len); 2433 tx_ring->tx_stats.tx_linearize++; 2434 } 2435 2436 /* need: 1 descriptor per page * PAGE_SIZE/IAVF_MAX_DATA_PER_TXD, 2437 * + 1 desc for skb_head_len/IAVF_MAX_DATA_PER_TXD, 2438 * + 4 desc gap to avoid the cache line where head is, 2439 * + 1 desc for context descriptor, 2440 * otherwise try next time 2441 */ 2442 if (iavf_maybe_stop_tx(tx_ring, count + 4 + 1)) { 2443 tx_ring->tx_stats.tx_busy++; 2444 return NETDEV_TX_BUSY; 2445 } 2446 2447 /* record the location of the first descriptor for this packet */ 2448 first = &tx_ring->tx_bi[tx_ring->next_to_use]; 2449 first->skb = skb; 2450 first->bytecount = skb->len; 2451 first->gso_segs = 1; 2452 2453 /* prepare the xmit flags */ 2454 if (iavf_tx_prepare_vlan_flags(skb, tx_ring, &tx_flags)) 2455 goto out_drop; 2456 2457 /* obtain protocol of skb */ 2458 protocol = vlan_get_protocol(skb); 2459 2460 /* setup IPv4/IPv6 offloads */ 2461 if (protocol == htons(ETH_P_IP)) 2462 tx_flags |= IAVF_TX_FLAGS_IPV4; 2463 else if (protocol == htons(ETH_P_IPV6)) 2464 tx_flags |= IAVF_TX_FLAGS_IPV6; 2465 2466 tso = iavf_tso(first, &hdr_len, &cd_type_cmd_tso_mss); 2467 2468 if (tso < 0) 2469 goto out_drop; 2470 else if (tso) 2471 tx_flags |= IAVF_TX_FLAGS_TSO; 2472 2473 /* Always offload the checksum, since it's in the data descriptor */ 2474 tso = iavf_tx_enable_csum(skb, &tx_flags, &td_cmd, &td_offset, 2475 tx_ring, &cd_tunneling); 2476 if (tso < 0) 2477 goto out_drop; 2478 2479 /* always enable CRC insertion offload */ 2480 td_cmd |= IAVF_TX_DESC_CMD_ICRC; 2481 2482 iavf_create_tx_ctx(tx_ring, cd_type_cmd_tso_mss, 2483 cd_tunneling, cd_l2tag2); 2484 2485 iavf_tx_map(tx_ring, skb, first, tx_flags, hdr_len, 2486 td_cmd, td_offset); 2487 2488 return NETDEV_TX_OK; 2489 2490 out_drop: 2491 iavf_trace(xmit_frame_ring_drop, first->skb, tx_ring); 2492 dev_kfree_skb_any(first->skb); 2493 first->skb = NULL; 2494 return NETDEV_TX_OK; 2495 } 2496 2497 /** 2498 * iavf_xmit_frame - Selects the correct VSI and Tx queue to send buffer 2499 * @skb: send buffer 2500 * @netdev: network interface device structure 2501 * 2502 * Returns NETDEV_TX_OK if sent, else an error code 2503 **/ 2504 netdev_tx_t iavf_xmit_frame(struct sk_buff *skb, struct net_device *netdev) 2505 { 2506 struct iavf_adapter *adapter = netdev_priv(netdev); 2507 struct iavf_ring *tx_ring = &adapter->tx_rings[skb->queue_mapping]; 2508 2509 /* hardware can't handle really short frames, hardware padding works 2510 * beyond this point 2511 */ 2512 if (unlikely(skb->len < IAVF_MIN_TX_LEN)) { 2513 if (skb_pad(skb, IAVF_MIN_TX_LEN - skb->len)) 2514 return NETDEV_TX_OK; 2515 skb->len = IAVF_MIN_TX_LEN; 2516 skb_set_tail_pointer(skb, IAVF_MIN_TX_LEN); 2517 } 2518 2519 return iavf_xmit_frame_ring(skb, tx_ring); 2520 } 2521