1 // SPDX-License-Identifier: ISC 2 /* 3 * Copyright (c) 2012-2017 Qualcomm Atheros, Inc. 4 * Copyright (c) 2018-2019, The Linux Foundation. All rights reserved. 5 */ 6 7 #include <linux/etherdevice.h> 8 #include <net/ieee80211_radiotap.h> 9 #include <linux/if_arp.h> 10 #include <linux/moduleparam.h> 11 #include <linux/ip.h> 12 #include <linux/ipv6.h> 13 #include <linux/if_vlan.h> 14 #include <net/ipv6.h> 15 #include <linux/prefetch.h> 16 17 #include "wil6210.h" 18 #include "wmi.h" 19 #include "txrx.h" 20 #include "trace.h" 21 #include "txrx_edma.h" 22 23 bool rx_align_2; 24 module_param(rx_align_2, bool, 0444); 25 MODULE_PARM_DESC(rx_align_2, " align Rx buffers on 4*n+2, default - no"); 26 27 bool rx_large_buf; 28 module_param(rx_large_buf, bool, 0444); 29 MODULE_PARM_DESC(rx_large_buf, " allocate 8KB RX buffers, default - no"); 30 31 /* Drop Tx packets in case Tx ring is full */ 32 bool drop_if_ring_full; 33 34 static inline uint wil_rx_snaplen(void) 35 { 36 return rx_align_2 ? 6 : 0; 37 } 38 39 /* wil_ring_wmark_low - low watermark for available descriptor space */ 40 static inline int wil_ring_wmark_low(struct wil_ring *ring) 41 { 42 return ring->size / 8; 43 } 44 45 /* wil_ring_wmark_high - high watermark for available descriptor space */ 46 static inline int wil_ring_wmark_high(struct wil_ring *ring) 47 { 48 return ring->size / 4; 49 } 50 51 /* returns true if num avail descriptors is lower than wmark_low */ 52 static inline int wil_ring_avail_low(struct wil_ring *ring) 53 { 54 return wil_ring_avail_tx(ring) < wil_ring_wmark_low(ring); 55 } 56 57 /* returns true if num avail descriptors is higher than wmark_high */ 58 static inline int wil_ring_avail_high(struct wil_ring *ring) 59 { 60 return wil_ring_avail_tx(ring) > wil_ring_wmark_high(ring); 61 } 62 63 /* returns true when all tx vrings are empty */ 64 bool wil_is_tx_idle(struct wil6210_priv *wil) 65 { 66 int i; 67 unsigned long data_comp_to; 68 int min_ring_id = wil_get_min_tx_ring_id(wil); 69 70 for (i = min_ring_id; i < WIL6210_MAX_TX_RINGS; i++) { 71 struct wil_ring *vring = &wil->ring_tx[i]; 72 int vring_index = vring - wil->ring_tx; 73 struct wil_ring_tx_data *txdata = 74 &wil->ring_tx_data[vring_index]; 75 76 spin_lock(&txdata->lock); 77 78 if (!vring->va || !txdata->enabled) { 79 spin_unlock(&txdata->lock); 80 continue; 81 } 82 83 data_comp_to = jiffies + msecs_to_jiffies( 84 WIL_DATA_COMPLETION_TO_MS); 85 if (test_bit(wil_status_napi_en, wil->status)) { 86 while (!wil_ring_is_empty(vring)) { 87 if (time_after(jiffies, data_comp_to)) { 88 wil_dbg_pm(wil, 89 "TO waiting for idle tx\n"); 90 spin_unlock(&txdata->lock); 91 return false; 92 } 93 wil_dbg_ratelimited(wil, 94 "tx vring is not empty -> NAPI\n"); 95 spin_unlock(&txdata->lock); 96 napi_synchronize(&wil->napi_tx); 97 msleep(20); 98 spin_lock(&txdata->lock); 99 if (!vring->va || !txdata->enabled) 100 break; 101 } 102 } 103 104 spin_unlock(&txdata->lock); 105 } 106 107 return true; 108 } 109 110 static int wil_vring_alloc(struct wil6210_priv *wil, struct wil_ring *vring) 111 { 112 struct device *dev = wil_to_dev(wil); 113 size_t sz = vring->size * sizeof(vring->va[0]); 114 uint i; 115 116 wil_dbg_misc(wil, "vring_alloc:\n"); 117 118 BUILD_BUG_ON(sizeof(vring->va[0]) != 32); 119 120 vring->swhead = 0; 121 vring->swtail = 0; 122 vring->ctx = kcalloc(vring->size, sizeof(vring->ctx[0]), GFP_KERNEL); 123 if (!vring->ctx) { 124 vring->va = NULL; 125 return -ENOMEM; 126 } 127 128 /* vring->va should be aligned on its size rounded up to power of 2 129 * This is granted by the dma_alloc_coherent. 130 * 131 * HW has limitation that all vrings addresses must share the same 132 * upper 16 msb bits part of 48 bits address. To workaround that, 133 * if we are using more than 32 bit addresses switch to 32 bit 134 * allocation before allocating vring memory. 135 * 136 * There's no check for the return value of dma_set_mask_and_coherent, 137 * since we assume if we were able to set the mask during 138 * initialization in this system it will not fail if we set it again 139 */ 140 if (wil->dma_addr_size > 32) 141 dma_set_mask_and_coherent(dev, DMA_BIT_MASK(32)); 142 143 vring->va = dma_alloc_coherent(dev, sz, &vring->pa, GFP_KERNEL); 144 if (!vring->va) { 145 kfree(vring->ctx); 146 vring->ctx = NULL; 147 return -ENOMEM; 148 } 149 150 if (wil->dma_addr_size > 32) 151 dma_set_mask_and_coherent(dev, 152 DMA_BIT_MASK(wil->dma_addr_size)); 153 154 /* initially, all descriptors are SW owned 155 * For Tx and Rx, ownership bit is at the same location, thus 156 * we can use any 157 */ 158 for (i = 0; i < vring->size; i++) { 159 volatile struct vring_tx_desc *_d = 160 &vring->va[i].tx.legacy; 161 162 _d->dma.status = TX_DMA_STATUS_DU; 163 } 164 165 wil_dbg_misc(wil, "vring[%d] 0x%p:%pad 0x%p\n", vring->size, 166 vring->va, &vring->pa, vring->ctx); 167 168 return 0; 169 } 170 171 static void wil_txdesc_unmap(struct device *dev, union wil_tx_desc *desc, 172 struct wil_ctx *ctx) 173 { 174 struct vring_tx_desc *d = &desc->legacy; 175 dma_addr_t pa = wil_desc_addr(&d->dma.addr); 176 u16 dmalen = le16_to_cpu(d->dma.length); 177 178 switch (ctx->mapped_as) { 179 case wil_mapped_as_single: 180 dma_unmap_single(dev, pa, dmalen, DMA_TO_DEVICE); 181 break; 182 case wil_mapped_as_page: 183 dma_unmap_page(dev, pa, dmalen, DMA_TO_DEVICE); 184 break; 185 default: 186 break; 187 } 188 } 189 190 static void wil_vring_free(struct wil6210_priv *wil, struct wil_ring *vring) 191 { 192 struct device *dev = wil_to_dev(wil); 193 size_t sz = vring->size * sizeof(vring->va[0]); 194 195 lockdep_assert_held(&wil->mutex); 196 if (!vring->is_rx) { 197 int vring_index = vring - wil->ring_tx; 198 199 wil_dbg_misc(wil, "free Tx vring %d [%d] 0x%p:%pad 0x%p\n", 200 vring_index, vring->size, vring->va, 201 &vring->pa, vring->ctx); 202 } else { 203 wil_dbg_misc(wil, "free Rx vring [%d] 0x%p:%pad 0x%p\n", 204 vring->size, vring->va, 205 &vring->pa, vring->ctx); 206 } 207 208 while (!wil_ring_is_empty(vring)) { 209 dma_addr_t pa; 210 u16 dmalen; 211 struct wil_ctx *ctx; 212 213 if (!vring->is_rx) { 214 struct vring_tx_desc dd, *d = ⅆ 215 volatile struct vring_tx_desc *_d = 216 &vring->va[vring->swtail].tx.legacy; 217 218 ctx = &vring->ctx[vring->swtail]; 219 if (!ctx) { 220 wil_dbg_txrx(wil, 221 "ctx(%d) was already completed\n", 222 vring->swtail); 223 vring->swtail = wil_ring_next_tail(vring); 224 continue; 225 } 226 *d = *_d; 227 wil_txdesc_unmap(dev, (union wil_tx_desc *)d, ctx); 228 if (ctx->skb) 229 dev_kfree_skb_any(ctx->skb); 230 vring->swtail = wil_ring_next_tail(vring); 231 } else { /* rx */ 232 struct vring_rx_desc dd, *d = ⅆ 233 volatile struct vring_rx_desc *_d = 234 &vring->va[vring->swhead].rx.legacy; 235 236 ctx = &vring->ctx[vring->swhead]; 237 *d = *_d; 238 pa = wil_desc_addr(&d->dma.addr); 239 dmalen = le16_to_cpu(d->dma.length); 240 dma_unmap_single(dev, pa, dmalen, DMA_FROM_DEVICE); 241 kfree_skb(ctx->skb); 242 wil_ring_advance_head(vring, 1); 243 } 244 } 245 dma_free_coherent(dev, sz, (void *)vring->va, vring->pa); 246 kfree(vring->ctx); 247 vring->pa = 0; 248 vring->va = NULL; 249 vring->ctx = NULL; 250 } 251 252 /* Allocate one skb for Rx VRING 253 * 254 * Safe to call from IRQ 255 */ 256 static int wil_vring_alloc_skb(struct wil6210_priv *wil, struct wil_ring *vring, 257 u32 i, int headroom) 258 { 259 struct device *dev = wil_to_dev(wil); 260 unsigned int sz = wil->rx_buf_len + ETH_HLEN + wil_rx_snaplen(); 261 struct vring_rx_desc dd, *d = ⅆ 262 volatile struct vring_rx_desc *_d = &vring->va[i].rx.legacy; 263 dma_addr_t pa; 264 struct sk_buff *skb = dev_alloc_skb(sz + headroom); 265 266 if (unlikely(!skb)) 267 return -ENOMEM; 268 269 skb_reserve(skb, headroom); 270 skb_put(skb, sz); 271 272 /** 273 * Make sure that the network stack calculates checksum for packets 274 * which failed the HW checksum calculation 275 */ 276 skb->ip_summed = CHECKSUM_NONE; 277 278 pa = dma_map_single(dev, skb->data, skb->len, DMA_FROM_DEVICE); 279 if (unlikely(dma_mapping_error(dev, pa))) { 280 kfree_skb(skb); 281 return -ENOMEM; 282 } 283 284 d->dma.d0 = RX_DMA_D0_CMD_DMA_RT | RX_DMA_D0_CMD_DMA_IT; 285 wil_desc_addr_set(&d->dma.addr, pa); 286 /* ip_length don't care */ 287 /* b11 don't care */ 288 /* error don't care */ 289 d->dma.status = 0; /* BIT(0) should be 0 for HW_OWNED */ 290 d->dma.length = cpu_to_le16(sz); 291 *_d = *d; 292 vring->ctx[i].skb = skb; 293 294 return 0; 295 } 296 297 /* Adds radiotap header 298 * 299 * Any error indicated as "Bad FCS" 300 * 301 * Vendor data for 04:ce:14-1 (Wilocity-1) consists of: 302 * - Rx descriptor: 32 bytes 303 * - Phy info 304 */ 305 static void wil_rx_add_radiotap_header(struct wil6210_priv *wil, 306 struct sk_buff *skb) 307 { 308 struct wil6210_rtap { 309 struct ieee80211_radiotap_header rthdr; 310 /* fields should be in the order of bits in rthdr.it_present */ 311 /* flags */ 312 u8 flags; 313 /* channel */ 314 __le16 chnl_freq __aligned(2); 315 __le16 chnl_flags; 316 /* MCS */ 317 u8 mcs_present; 318 u8 mcs_flags; 319 u8 mcs_index; 320 } __packed; 321 struct vring_rx_desc *d = wil_skb_rxdesc(skb); 322 struct wil6210_rtap *rtap; 323 int rtap_len = sizeof(struct wil6210_rtap); 324 struct ieee80211_channel *ch = wil->monitor_chandef.chan; 325 326 if (skb_headroom(skb) < rtap_len && 327 pskb_expand_head(skb, rtap_len, 0, GFP_ATOMIC)) { 328 wil_err(wil, "Unable to expand headroom to %d\n", rtap_len); 329 return; 330 } 331 332 rtap = skb_push(skb, rtap_len); 333 memset(rtap, 0, rtap_len); 334 335 rtap->rthdr.it_version = PKTHDR_RADIOTAP_VERSION; 336 rtap->rthdr.it_len = cpu_to_le16(rtap_len); 337 rtap->rthdr.it_present = cpu_to_le32((1 << IEEE80211_RADIOTAP_FLAGS) | 338 (1 << IEEE80211_RADIOTAP_CHANNEL) | 339 (1 << IEEE80211_RADIOTAP_MCS)); 340 if (d->dma.status & RX_DMA_STATUS_ERROR) 341 rtap->flags |= IEEE80211_RADIOTAP_F_BADFCS; 342 343 rtap->chnl_freq = cpu_to_le16(ch ? ch->center_freq : 58320); 344 rtap->chnl_flags = cpu_to_le16(0); 345 346 rtap->mcs_present = IEEE80211_RADIOTAP_MCS_HAVE_MCS; 347 rtap->mcs_flags = 0; 348 rtap->mcs_index = wil_rxdesc_mcs(d); 349 } 350 351 static bool wil_is_rx_idle(struct wil6210_priv *wil) 352 { 353 struct vring_rx_desc *_d; 354 struct wil_ring *ring = &wil->ring_rx; 355 356 _d = (struct vring_rx_desc *)&ring->va[ring->swhead].rx.legacy; 357 if (_d->dma.status & RX_DMA_STATUS_DU) 358 return false; 359 360 return true; 361 } 362 363 static int wil_rx_get_cid_by_skb(struct wil6210_priv *wil, struct sk_buff *skb) 364 { 365 struct vring_rx_desc *d = wil_skb_rxdesc(skb); 366 int mid = wil_rxdesc_mid(d); 367 struct wil6210_vif *vif = wil->vifs[mid]; 368 /* cid from DMA descriptor is limited to 3 bits. 369 * In case of cid>=8, the value would be cid modulo 8 and we need to 370 * find real cid by locating the transmitter (ta) inside sta array 371 */ 372 int cid = wil_rxdesc_cid(d); 373 unsigned int snaplen = wil_rx_snaplen(); 374 struct ieee80211_hdr_3addr *hdr; 375 int i; 376 unsigned char *ta; 377 u8 ftype; 378 379 /* in monitor mode there are no connections */ 380 if (vif->wdev.iftype == NL80211_IFTYPE_MONITOR) 381 return cid; 382 383 ftype = wil_rxdesc_ftype(d) << 2; 384 if (likely(ftype == IEEE80211_FTYPE_DATA)) { 385 if (unlikely(skb->len < ETH_HLEN + snaplen)) { 386 wil_err_ratelimited(wil, 387 "Short data frame, len = %d\n", 388 skb->len); 389 return -ENOENT; 390 } 391 ta = wil_skb_get_sa(skb); 392 } else { 393 if (unlikely(skb->len < sizeof(struct ieee80211_hdr_3addr))) { 394 wil_err_ratelimited(wil, "Short frame, len = %d\n", 395 skb->len); 396 return -ENOENT; 397 } 398 hdr = (void *)skb->data; 399 ta = hdr->addr2; 400 } 401 402 if (wil->max_assoc_sta <= WIL6210_RX_DESC_MAX_CID) 403 return cid; 404 405 /* assuming no concurrency between AP interfaces and STA interfaces. 406 * multista is used only in P2P_GO or AP mode. In other modes return 407 * cid from the rx descriptor 408 */ 409 if (vif->wdev.iftype != NL80211_IFTYPE_P2P_GO && 410 vif->wdev.iftype != NL80211_IFTYPE_AP) 411 return cid; 412 413 /* For Rx packets cid from rx descriptor is limited to 3 bits (0..7), 414 * to find the real cid, compare transmitter address with the stored 415 * stations mac address in the driver sta array 416 */ 417 for (i = cid; i < wil->max_assoc_sta; i += WIL6210_RX_DESC_MAX_CID) { 418 if (wil->sta[i].status != wil_sta_unused && 419 ether_addr_equal(wil->sta[i].addr, ta)) { 420 cid = i; 421 break; 422 } 423 } 424 if (i >= wil->max_assoc_sta) { 425 wil_err_ratelimited(wil, "Could not find cid for frame with transmit addr = %pM, iftype = %d, frametype = %d, len = %d\n", 426 ta, vif->wdev.iftype, ftype, skb->len); 427 cid = -ENOENT; 428 } 429 430 return cid; 431 } 432 433 /* reap 1 frame from @swhead 434 * 435 * Rx descriptor copied to skb->cb 436 * 437 * Safe to call from IRQ 438 */ 439 static struct sk_buff *wil_vring_reap_rx(struct wil6210_priv *wil, 440 struct wil_ring *vring) 441 { 442 struct device *dev = wil_to_dev(wil); 443 struct wil6210_vif *vif; 444 struct net_device *ndev; 445 volatile struct vring_rx_desc *_d; 446 struct vring_rx_desc *d; 447 struct sk_buff *skb; 448 dma_addr_t pa; 449 unsigned int snaplen = wil_rx_snaplen(); 450 unsigned int sz = wil->rx_buf_len + ETH_HLEN + snaplen; 451 u16 dmalen; 452 u8 ftype; 453 int cid, mid; 454 int i; 455 struct wil_net_stats *stats; 456 457 BUILD_BUG_ON(sizeof(struct skb_rx_info) > sizeof(skb->cb)); 458 459 again: 460 if (unlikely(wil_ring_is_empty(vring))) 461 return NULL; 462 463 i = (int)vring->swhead; 464 _d = &vring->va[i].rx.legacy; 465 if (unlikely(!(_d->dma.status & RX_DMA_STATUS_DU))) { 466 /* it is not error, we just reached end of Rx done area */ 467 return NULL; 468 } 469 470 skb = vring->ctx[i].skb; 471 vring->ctx[i].skb = NULL; 472 wil_ring_advance_head(vring, 1); 473 if (!skb) { 474 wil_err(wil, "No Rx skb at [%d]\n", i); 475 goto again; 476 } 477 d = wil_skb_rxdesc(skb); 478 *d = *_d; 479 pa = wil_desc_addr(&d->dma.addr); 480 481 dma_unmap_single(dev, pa, sz, DMA_FROM_DEVICE); 482 dmalen = le16_to_cpu(d->dma.length); 483 484 trace_wil6210_rx(i, d); 485 wil_dbg_txrx(wil, "Rx[%3d] : %d bytes\n", i, dmalen); 486 wil_hex_dump_txrx("RxD ", DUMP_PREFIX_NONE, 32, 4, 487 (const void *)d, sizeof(*d), false); 488 489 mid = wil_rxdesc_mid(d); 490 vif = wil->vifs[mid]; 491 492 if (unlikely(!vif)) { 493 wil_dbg_txrx(wil, "skipped RX descriptor with invalid mid %d", 494 mid); 495 kfree_skb(skb); 496 goto again; 497 } 498 ndev = vif_to_ndev(vif); 499 if (unlikely(dmalen > sz)) { 500 wil_err_ratelimited(wil, "Rx size too large: %d bytes!\n", 501 dmalen); 502 kfree_skb(skb); 503 goto again; 504 } 505 skb_trim(skb, dmalen); 506 507 prefetch(skb->data); 508 509 wil_hex_dump_txrx("Rx ", DUMP_PREFIX_OFFSET, 16, 1, 510 skb->data, skb_headlen(skb), false); 511 512 cid = wil_rx_get_cid_by_skb(wil, skb); 513 if (cid == -ENOENT) { 514 kfree_skb(skb); 515 goto again; 516 } 517 wil_skb_set_cid(skb, (u8)cid); 518 stats = &wil->sta[cid].stats; 519 520 stats->last_mcs_rx = wil_rxdesc_mcs(d); 521 if (stats->last_mcs_rx < ARRAY_SIZE(stats->rx_per_mcs)) 522 stats->rx_per_mcs[stats->last_mcs_rx]++; 523 524 /* use radiotap header only if required */ 525 if (ndev->type == ARPHRD_IEEE80211_RADIOTAP) 526 wil_rx_add_radiotap_header(wil, skb); 527 528 /* no extra checks if in sniffer mode */ 529 if (ndev->type != ARPHRD_ETHER) 530 return skb; 531 /* Non-data frames may be delivered through Rx DMA channel (ex: BAR) 532 * Driver should recognize it by frame type, that is found 533 * in Rx descriptor. If type is not data, it is 802.11 frame as is 534 */ 535 ftype = wil_rxdesc_ftype(d) << 2; 536 if (unlikely(ftype != IEEE80211_FTYPE_DATA)) { 537 u8 fc1 = wil_rxdesc_fc1(d); 538 int tid = wil_rxdesc_tid(d); 539 u16 seq = wil_rxdesc_seq(d); 540 541 wil_dbg_txrx(wil, 542 "Non-data frame FC[7:0] 0x%02x MID %d CID %d TID %d Seq 0x%03x\n", 543 fc1, mid, cid, tid, seq); 544 stats->rx_non_data_frame++; 545 if (wil_is_back_req(fc1)) { 546 wil_dbg_txrx(wil, 547 "BAR: MID %d CID %d TID %d Seq 0x%03x\n", 548 mid, cid, tid, seq); 549 wil_rx_bar(wil, vif, cid, tid, seq); 550 } else { 551 /* print again all info. One can enable only this 552 * without overhead for printing every Rx frame 553 */ 554 wil_dbg_txrx(wil, 555 "Unhandled non-data frame FC[7:0] 0x%02x MID %d CID %d TID %d Seq 0x%03x\n", 556 fc1, mid, cid, tid, seq); 557 wil_hex_dump_txrx("RxD ", DUMP_PREFIX_NONE, 32, 4, 558 (const void *)d, sizeof(*d), false); 559 wil_hex_dump_txrx("Rx ", DUMP_PREFIX_OFFSET, 16, 1, 560 skb->data, skb_headlen(skb), false); 561 } 562 kfree_skb(skb); 563 goto again; 564 } 565 566 /* L4 IDENT is on when HW calculated checksum, check status 567 * and in case of error drop the packet 568 * higher stack layers will handle retransmission (if required) 569 */ 570 if (likely(d->dma.status & RX_DMA_STATUS_L4I)) { 571 /* L4 protocol identified, csum calculated */ 572 if (likely((d->dma.error & RX_DMA_ERROR_L4_ERR) == 0)) 573 skb->ip_summed = CHECKSUM_UNNECESSARY; 574 /* If HW reports bad checksum, let IP stack re-check it 575 * For example, HW don't understand Microsoft IP stack that 576 * mis-calculates TCP checksum - if it should be 0x0, 577 * it writes 0xffff in violation of RFC 1624 578 */ 579 else 580 stats->rx_csum_err++; 581 } 582 583 if (snaplen) { 584 /* Packet layout 585 * +-------+-------+---------+------------+------+ 586 * | SA(6) | DA(6) | SNAP(6) | ETHTYPE(2) | DATA | 587 * +-------+-------+---------+------------+------+ 588 * Need to remove SNAP, shifting SA and DA forward 589 */ 590 memmove(skb->data + snaplen, skb->data, 2 * ETH_ALEN); 591 skb_pull(skb, snaplen); 592 } 593 594 return skb; 595 } 596 597 /* allocate and fill up to @count buffers in rx ring 598 * buffers posted at @swtail 599 * Note: we have a single RX queue for servicing all VIFs, but we 600 * allocate skbs with headroom according to main interface only. This 601 * means it will not work with monitor interface together with other VIFs. 602 * Currently we only support monitor interface on its own without other VIFs, 603 * and we will need to fix this code once we add support. 604 */ 605 static int wil_rx_refill(struct wil6210_priv *wil, int count) 606 { 607 struct net_device *ndev = wil->main_ndev; 608 struct wil_ring *v = &wil->ring_rx; 609 u32 next_tail; 610 int rc = 0; 611 int headroom = ndev->type == ARPHRD_IEEE80211_RADIOTAP ? 612 WIL6210_RTAP_SIZE : 0; 613 614 for (; next_tail = wil_ring_next_tail(v), 615 (next_tail != v->swhead) && (count-- > 0); 616 v->swtail = next_tail) { 617 rc = wil_vring_alloc_skb(wil, v, v->swtail, headroom); 618 if (unlikely(rc)) { 619 wil_err_ratelimited(wil, "Error %d in rx refill[%d]\n", 620 rc, v->swtail); 621 break; 622 } 623 } 624 625 /* make sure all writes to descriptors (shared memory) are done before 626 * committing them to HW 627 */ 628 wmb(); 629 630 wil_w(wil, v->hwtail, v->swtail); 631 632 return rc; 633 } 634 635 /** 636 * reverse_memcmp - Compare two areas of memory, in reverse order 637 * @cs: One area of memory 638 * @ct: Another area of memory 639 * @count: The size of the area. 640 * 641 * Cut'n'paste from original memcmp (see lib/string.c) 642 * with minimal modifications 643 */ 644 int reverse_memcmp(const void *cs, const void *ct, size_t count) 645 { 646 const unsigned char *su1, *su2; 647 int res = 0; 648 649 for (su1 = cs + count - 1, su2 = ct + count - 1; count > 0; 650 --su1, --su2, count--) { 651 res = *su1 - *su2; 652 if (res) 653 break; 654 } 655 return res; 656 } 657 658 static int wil_rx_crypto_check(struct wil6210_priv *wil, struct sk_buff *skb) 659 { 660 struct vring_rx_desc *d = wil_skb_rxdesc(skb); 661 int cid = wil_skb_get_cid(skb); 662 int tid = wil_rxdesc_tid(d); 663 int key_id = wil_rxdesc_key_id(d); 664 int mc = wil_rxdesc_mcast(d); 665 struct wil_sta_info *s = &wil->sta[cid]; 666 struct wil_tid_crypto_rx *c = mc ? &s->group_crypto_rx : 667 &s->tid_crypto_rx[tid]; 668 struct wil_tid_crypto_rx_single *cc = &c->key_id[key_id]; 669 const u8 *pn = (u8 *)&d->mac.pn_15_0; 670 671 if (!cc->key_set) { 672 wil_err_ratelimited(wil, 673 "Key missing. CID %d TID %d MCast %d KEY_ID %d\n", 674 cid, tid, mc, key_id); 675 return -EINVAL; 676 } 677 678 if (reverse_memcmp(pn, cc->pn, IEEE80211_GCMP_PN_LEN) <= 0) { 679 wil_err_ratelimited(wil, 680 "Replay attack. CID %d TID %d MCast %d KEY_ID %d PN %6phN last %6phN\n", 681 cid, tid, mc, key_id, pn, cc->pn); 682 return -EINVAL; 683 } 684 memcpy(cc->pn, pn, IEEE80211_GCMP_PN_LEN); 685 686 return 0; 687 } 688 689 static int wil_rx_error_check(struct wil6210_priv *wil, struct sk_buff *skb, 690 struct wil_net_stats *stats) 691 { 692 struct vring_rx_desc *d = wil_skb_rxdesc(skb); 693 694 if ((d->dma.status & RX_DMA_STATUS_ERROR) && 695 (d->dma.error & RX_DMA_ERROR_MIC)) { 696 stats->rx_mic_error++; 697 wil_dbg_txrx(wil, "MIC error, dropping packet\n"); 698 return -EFAULT; 699 } 700 701 return 0; 702 } 703 704 static void wil_get_netif_rx_params(struct sk_buff *skb, int *cid, 705 int *security) 706 { 707 struct vring_rx_desc *d = wil_skb_rxdesc(skb); 708 709 *cid = wil_skb_get_cid(skb); 710 *security = wil_rxdesc_security(d); 711 } 712 713 /* 714 * Check if skb is ptk eapol key message 715 * 716 * returns a pointer to the start of the eapol key structure, NULL 717 * if frame is not PTK eapol key 718 */ 719 static struct wil_eapol_key *wil_is_ptk_eapol_key(struct wil6210_priv *wil, 720 struct sk_buff *skb) 721 { 722 u8 *buf; 723 const struct wil_1x_hdr *hdr; 724 struct wil_eapol_key *key; 725 u16 key_info; 726 int len = skb->len; 727 728 if (!skb_mac_header_was_set(skb)) { 729 wil_err(wil, "mac header was not set\n"); 730 return NULL; 731 } 732 733 len -= skb_mac_offset(skb); 734 735 if (len < sizeof(struct ethhdr) + sizeof(struct wil_1x_hdr) + 736 sizeof(struct wil_eapol_key)) 737 return NULL; 738 739 buf = skb_mac_header(skb) + sizeof(struct ethhdr); 740 741 hdr = (const struct wil_1x_hdr *)buf; 742 if (hdr->type != WIL_1X_TYPE_EAPOL_KEY) 743 return NULL; 744 745 key = (struct wil_eapol_key *)(buf + sizeof(struct wil_1x_hdr)); 746 if (key->type != WIL_EAPOL_KEY_TYPE_WPA && 747 key->type != WIL_EAPOL_KEY_TYPE_RSN) 748 return NULL; 749 750 key_info = be16_to_cpu(key->key_info); 751 if (!(key_info & WIL_KEY_INFO_KEY_TYPE)) /* check if pairwise */ 752 return NULL; 753 754 return key; 755 } 756 757 static bool wil_skb_is_eap_3(struct wil6210_priv *wil, struct sk_buff *skb) 758 { 759 struct wil_eapol_key *key; 760 u16 key_info; 761 762 key = wil_is_ptk_eapol_key(wil, skb); 763 if (!key) 764 return false; 765 766 key_info = be16_to_cpu(key->key_info); 767 if (key_info & (WIL_KEY_INFO_MIC | 768 WIL_KEY_INFO_ENCR_KEY_DATA)) { 769 /* 3/4 of 4-Way Handshake */ 770 wil_dbg_misc(wil, "EAPOL key message 3\n"); 771 return true; 772 } 773 /* 1/4 of 4-Way Handshake */ 774 wil_dbg_misc(wil, "EAPOL key message 1\n"); 775 776 return false; 777 } 778 779 static bool wil_skb_is_eap_4(struct wil6210_priv *wil, struct sk_buff *skb) 780 { 781 struct wil_eapol_key *key; 782 u32 *nonce, i; 783 784 key = wil_is_ptk_eapol_key(wil, skb); 785 if (!key) 786 return false; 787 788 nonce = (u32 *)key->key_nonce; 789 for (i = 0; i < WIL_EAP_NONCE_LEN / sizeof(u32); i++, nonce++) { 790 if (*nonce != 0) { 791 /* message 2/4 */ 792 wil_dbg_misc(wil, "EAPOL key message 2\n"); 793 return false; 794 } 795 } 796 wil_dbg_misc(wil, "EAPOL key message 4\n"); 797 798 return true; 799 } 800 801 void wil_enable_tx_key_worker(struct work_struct *work) 802 { 803 struct wil6210_vif *vif = container_of(work, 804 struct wil6210_vif, enable_tx_key_worker); 805 struct wil6210_priv *wil = vif_to_wil(vif); 806 int rc, cid; 807 808 rtnl_lock(); 809 if (vif->ptk_rekey_state != WIL_REKEY_WAIT_M4_SENT) { 810 wil_dbg_misc(wil, "Invalid rekey state = %d\n", 811 vif->ptk_rekey_state); 812 rtnl_unlock(); 813 return; 814 } 815 816 cid = wil_find_cid_by_idx(wil, vif->mid, 0); 817 if (!wil_cid_valid(wil, cid)) { 818 wil_err(wil, "Invalid cid = %d\n", cid); 819 rtnl_unlock(); 820 return; 821 } 822 823 wil_dbg_misc(wil, "Apply PTK key after eapol was sent out\n"); 824 rc = wmi_add_cipher_key(vif, 0, wil->sta[cid].addr, 0, NULL, 825 WMI_KEY_USE_APPLY_PTK); 826 827 vif->ptk_rekey_state = WIL_REKEY_IDLE; 828 rtnl_unlock(); 829 830 if (rc) 831 wil_err(wil, "Apply PTK key failed %d\n", rc); 832 } 833 834 void wil_tx_complete_handle_eapol(struct wil6210_vif *vif, struct sk_buff *skb) 835 { 836 struct wil6210_priv *wil = vif_to_wil(vif); 837 struct wireless_dev *wdev = vif_to_wdev(vif); 838 bool q = false; 839 840 if (wdev->iftype != NL80211_IFTYPE_STATION || 841 !test_bit(WMI_FW_CAPABILITY_SPLIT_REKEY, wil->fw_capabilities)) 842 return; 843 844 /* check if skb is an EAP message 4/4 */ 845 if (!wil_skb_is_eap_4(wil, skb)) 846 return; 847 848 spin_lock_bh(&wil->eap_lock); 849 switch (vif->ptk_rekey_state) { 850 case WIL_REKEY_IDLE: 851 /* ignore idle state, can happen due to M4 retransmission */ 852 break; 853 case WIL_REKEY_M3_RECEIVED: 854 vif->ptk_rekey_state = WIL_REKEY_IDLE; 855 break; 856 case WIL_REKEY_WAIT_M4_SENT: 857 q = true; 858 break; 859 default: 860 wil_err(wil, "Unknown rekey state = %d", 861 vif->ptk_rekey_state); 862 } 863 spin_unlock_bh(&wil->eap_lock); 864 865 if (q) { 866 q = queue_work(wil->wmi_wq, &vif->enable_tx_key_worker); 867 wil_dbg_misc(wil, "queue_work of enable_tx_key_worker -> %d\n", 868 q); 869 } 870 } 871 872 static void wil_rx_handle_eapol(struct wil6210_vif *vif, struct sk_buff *skb) 873 { 874 struct wil6210_priv *wil = vif_to_wil(vif); 875 struct wireless_dev *wdev = vif_to_wdev(vif); 876 877 if (wdev->iftype != NL80211_IFTYPE_STATION || 878 !test_bit(WMI_FW_CAPABILITY_SPLIT_REKEY, wil->fw_capabilities)) 879 return; 880 881 /* check if skb is a EAP message 3/4 */ 882 if (!wil_skb_is_eap_3(wil, skb)) 883 return; 884 885 if (vif->ptk_rekey_state == WIL_REKEY_IDLE) 886 vif->ptk_rekey_state = WIL_REKEY_M3_RECEIVED; 887 } 888 889 /* 890 * Pass Rx packet to the netif. Update statistics. 891 * Called in softirq context (NAPI poll). 892 */ 893 void wil_netif_rx(struct sk_buff *skb, struct net_device *ndev, int cid, 894 struct wil_net_stats *stats, bool gro) 895 { 896 struct wil6210_vif *vif = ndev_to_vif(ndev); 897 struct wil6210_priv *wil = ndev_to_wil(ndev); 898 struct wireless_dev *wdev = vif_to_wdev(vif); 899 unsigned int len = skb->len; 900 u8 *sa, *da = wil_skb_get_da(skb); 901 /* here looking for DA, not A1, thus Rxdesc's 'mcast' indication 902 * is not suitable, need to look at data 903 */ 904 int mcast = is_multicast_ether_addr(da); 905 struct sk_buff *xmit_skb = NULL; 906 907 if (wdev->iftype == NL80211_IFTYPE_STATION) { 908 sa = wil_skb_get_sa(skb); 909 if (mcast && ether_addr_equal(sa, ndev->dev_addr)) { 910 /* mcast packet looped back to us */ 911 dev_kfree_skb(skb); 912 ndev->stats.rx_dropped++; 913 stats->rx_dropped++; 914 wil_dbg_txrx(wil, "Rx drop %d bytes\n", len); 915 return; 916 } 917 } else if (wdev->iftype == NL80211_IFTYPE_AP && !vif->ap_isolate) { 918 if (mcast) { 919 /* send multicast frames both to higher layers in 920 * local net stack and back to the wireless medium 921 */ 922 xmit_skb = skb_copy(skb, GFP_ATOMIC); 923 } else { 924 int xmit_cid = wil_find_cid(wil, vif->mid, da); 925 926 if (xmit_cid >= 0) { 927 /* The destination station is associated to 928 * this AP (in this VLAN), so send the frame 929 * directly to it and do not pass it to local 930 * net stack. 931 */ 932 xmit_skb = skb; 933 skb = NULL; 934 } 935 } 936 } 937 if (xmit_skb) { 938 /* Send to wireless media and increase priority by 256 to 939 * keep the received priority instead of reclassifying 940 * the frame (see cfg80211_classify8021d). 941 */ 942 xmit_skb->dev = ndev; 943 xmit_skb->priority += 256; 944 xmit_skb->protocol = htons(ETH_P_802_3); 945 skb_reset_network_header(xmit_skb); 946 skb_reset_mac_header(xmit_skb); 947 wil_dbg_txrx(wil, "Rx -> Tx %d bytes\n", len); 948 dev_queue_xmit(xmit_skb); 949 } 950 951 if (skb) { /* deliver to local stack */ 952 skb->protocol = eth_type_trans(skb, ndev); 953 skb->dev = ndev; 954 955 if (skb->protocol == cpu_to_be16(ETH_P_PAE)) 956 wil_rx_handle_eapol(vif, skb); 957 958 if (gro) 959 napi_gro_receive(&wil->napi_rx, skb); 960 else 961 netif_rx_ni(skb); 962 } 963 ndev->stats.rx_packets++; 964 stats->rx_packets++; 965 ndev->stats.rx_bytes += len; 966 stats->rx_bytes += len; 967 if (mcast) 968 ndev->stats.multicast++; 969 } 970 971 void wil_netif_rx_any(struct sk_buff *skb, struct net_device *ndev) 972 { 973 int cid, security; 974 struct wil6210_priv *wil = ndev_to_wil(ndev); 975 struct wil_net_stats *stats; 976 977 wil->txrx_ops.get_netif_rx_params(skb, &cid, &security); 978 979 stats = &wil->sta[cid].stats; 980 981 skb_orphan(skb); 982 983 if (security && (wil->txrx_ops.rx_crypto_check(wil, skb) != 0)) { 984 wil_dbg_txrx(wil, "Rx drop %d bytes\n", skb->len); 985 dev_kfree_skb(skb); 986 ndev->stats.rx_dropped++; 987 stats->rx_replay++; 988 stats->rx_dropped++; 989 return; 990 } 991 992 /* check errors reported by HW and update statistics */ 993 if (unlikely(wil->txrx_ops.rx_error_check(wil, skb, stats))) { 994 dev_kfree_skb(skb); 995 return; 996 } 997 998 wil_netif_rx(skb, ndev, cid, stats, true); 999 } 1000 1001 /* Proceed all completed skb's from Rx VRING 1002 * 1003 * Safe to call from NAPI poll, i.e. softirq with interrupts enabled 1004 */ 1005 void wil_rx_handle(struct wil6210_priv *wil, int *quota) 1006 { 1007 struct net_device *ndev = wil->main_ndev; 1008 struct wireless_dev *wdev = ndev->ieee80211_ptr; 1009 struct wil_ring *v = &wil->ring_rx; 1010 struct sk_buff *skb; 1011 1012 if (unlikely(!v->va)) { 1013 wil_err(wil, "Rx IRQ while Rx not yet initialized\n"); 1014 return; 1015 } 1016 wil_dbg_txrx(wil, "rx_handle\n"); 1017 while ((*quota > 0) && (NULL != (skb = wil_vring_reap_rx(wil, v)))) { 1018 (*quota)--; 1019 1020 /* monitor is currently supported on main interface only */ 1021 if (wdev->iftype == NL80211_IFTYPE_MONITOR) { 1022 skb->dev = ndev; 1023 skb_reset_mac_header(skb); 1024 skb->ip_summed = CHECKSUM_UNNECESSARY; 1025 skb->pkt_type = PACKET_OTHERHOST; 1026 skb->protocol = htons(ETH_P_802_2); 1027 wil_netif_rx_any(skb, ndev); 1028 } else { 1029 wil_rx_reorder(wil, skb); 1030 } 1031 } 1032 wil_rx_refill(wil, v->size); 1033 } 1034 1035 static void wil_rx_buf_len_init(struct wil6210_priv *wil) 1036 { 1037 wil->rx_buf_len = rx_large_buf ? 1038 WIL_MAX_ETH_MTU : TXRX_BUF_LEN_DEFAULT - WIL_MAX_MPDU_OVERHEAD; 1039 if (mtu_max > wil->rx_buf_len) { 1040 /* do not allow RX buffers to be smaller than mtu_max, for 1041 * backward compatibility (mtu_max parameter was also used 1042 * to support receiving large packets) 1043 */ 1044 wil_info(wil, "Override RX buffer to mtu_max(%d)\n", mtu_max); 1045 wil->rx_buf_len = mtu_max; 1046 } 1047 } 1048 1049 static int wil_rx_init(struct wil6210_priv *wil, uint order) 1050 { 1051 struct wil_ring *vring = &wil->ring_rx; 1052 int rc; 1053 1054 wil_dbg_misc(wil, "rx_init\n"); 1055 1056 if (vring->va) { 1057 wil_err(wil, "Rx ring already allocated\n"); 1058 return -EINVAL; 1059 } 1060 1061 wil_rx_buf_len_init(wil); 1062 1063 vring->size = 1 << order; 1064 vring->is_rx = true; 1065 rc = wil_vring_alloc(wil, vring); 1066 if (rc) 1067 return rc; 1068 1069 rc = wmi_rx_chain_add(wil, vring); 1070 if (rc) 1071 goto err_free; 1072 1073 rc = wil_rx_refill(wil, vring->size); 1074 if (rc) 1075 goto err_free; 1076 1077 return 0; 1078 err_free: 1079 wil_vring_free(wil, vring); 1080 1081 return rc; 1082 } 1083 1084 static void wil_rx_fini(struct wil6210_priv *wil) 1085 { 1086 struct wil_ring *vring = &wil->ring_rx; 1087 1088 wil_dbg_misc(wil, "rx_fini\n"); 1089 1090 if (vring->va) 1091 wil_vring_free(wil, vring); 1092 } 1093 1094 static int wil_tx_desc_map(union wil_tx_desc *desc, dma_addr_t pa, 1095 u32 len, int vring_index) 1096 { 1097 struct vring_tx_desc *d = &desc->legacy; 1098 1099 wil_desc_addr_set(&d->dma.addr, pa); 1100 d->dma.ip_length = 0; 1101 /* 0..6: mac_length; 7:ip_version 0-IP6 1-IP4*/ 1102 d->dma.b11 = 0/*14 | BIT(7)*/; 1103 d->dma.error = 0; 1104 d->dma.status = 0; /* BIT(0) should be 0 for HW_OWNED */ 1105 d->dma.length = cpu_to_le16((u16)len); 1106 d->dma.d0 = (vring_index << DMA_CFG_DESC_TX_0_QID_POS); 1107 d->mac.d[0] = 0; 1108 d->mac.d[1] = 0; 1109 d->mac.d[2] = 0; 1110 d->mac.ucode_cmd = 0; 1111 /* translation type: 0 - bypass; 1 - 802.3; 2 - native wifi */ 1112 d->mac.d[2] = BIT(MAC_CFG_DESC_TX_2_SNAP_HDR_INSERTION_EN_POS) | 1113 (1 << MAC_CFG_DESC_TX_2_L2_TRANSLATION_TYPE_POS); 1114 1115 return 0; 1116 } 1117 1118 void wil_tx_data_init(struct wil_ring_tx_data *txdata) 1119 { 1120 spin_lock_bh(&txdata->lock); 1121 txdata->dot1x_open = false; 1122 txdata->enabled = 0; 1123 txdata->idle = 0; 1124 txdata->last_idle = 0; 1125 txdata->begin = 0; 1126 txdata->agg_wsize = 0; 1127 txdata->agg_timeout = 0; 1128 txdata->agg_amsdu = 0; 1129 txdata->addba_in_progress = false; 1130 txdata->mid = U8_MAX; 1131 spin_unlock_bh(&txdata->lock); 1132 } 1133 1134 static int wil_vring_init_tx(struct wil6210_vif *vif, int id, int size, 1135 int cid, int tid) 1136 { 1137 struct wil6210_priv *wil = vif_to_wil(vif); 1138 int rc; 1139 struct wmi_vring_cfg_cmd cmd = { 1140 .action = cpu_to_le32(WMI_VRING_CMD_ADD), 1141 .vring_cfg = { 1142 .tx_sw_ring = { 1143 .max_mpdu_size = 1144 cpu_to_le16(wil_mtu2macbuf(mtu_max)), 1145 .ring_size = cpu_to_le16(size), 1146 }, 1147 .ringid = id, 1148 .encap_trans_type = WMI_VRING_ENC_TYPE_802_3, 1149 .mac_ctrl = 0, 1150 .to_resolution = 0, 1151 .agg_max_wsize = 0, 1152 .schd_params = { 1153 .priority = cpu_to_le16(0), 1154 .timeslot_us = cpu_to_le16(0xfff), 1155 }, 1156 }, 1157 }; 1158 struct { 1159 struct wmi_cmd_hdr wmi; 1160 struct wmi_vring_cfg_done_event cmd; 1161 } __packed reply = { 1162 .cmd = {.status = WMI_FW_STATUS_FAILURE}, 1163 }; 1164 struct wil_ring *vring = &wil->ring_tx[id]; 1165 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[id]; 1166 1167 if (cid >= WIL6210_RX_DESC_MAX_CID) { 1168 cmd.vring_cfg.cidxtid = CIDXTID_EXTENDED_CID_TID; 1169 cmd.vring_cfg.cid = cid; 1170 cmd.vring_cfg.tid = tid; 1171 } else { 1172 cmd.vring_cfg.cidxtid = mk_cidxtid(cid, tid); 1173 } 1174 1175 wil_dbg_misc(wil, "vring_init_tx: max_mpdu_size %d\n", 1176 cmd.vring_cfg.tx_sw_ring.max_mpdu_size); 1177 lockdep_assert_held(&wil->mutex); 1178 1179 if (vring->va) { 1180 wil_err(wil, "Tx ring [%d] already allocated\n", id); 1181 rc = -EINVAL; 1182 goto out; 1183 } 1184 1185 wil_tx_data_init(txdata); 1186 vring->is_rx = false; 1187 vring->size = size; 1188 rc = wil_vring_alloc(wil, vring); 1189 if (rc) 1190 goto out; 1191 1192 wil->ring2cid_tid[id][0] = cid; 1193 wil->ring2cid_tid[id][1] = tid; 1194 1195 cmd.vring_cfg.tx_sw_ring.ring_mem_base = cpu_to_le64(vring->pa); 1196 1197 if (!vif->privacy) 1198 txdata->dot1x_open = true; 1199 rc = wmi_call(wil, WMI_VRING_CFG_CMDID, vif->mid, &cmd, sizeof(cmd), 1200 WMI_VRING_CFG_DONE_EVENTID, &reply, sizeof(reply), 1201 WIL_WMI_CALL_GENERAL_TO_MS); 1202 if (rc) 1203 goto out_free; 1204 1205 if (reply.cmd.status != WMI_FW_STATUS_SUCCESS) { 1206 wil_err(wil, "Tx config failed, status 0x%02x\n", 1207 reply.cmd.status); 1208 rc = -EINVAL; 1209 goto out_free; 1210 } 1211 1212 spin_lock_bh(&txdata->lock); 1213 vring->hwtail = le32_to_cpu(reply.cmd.tx_vring_tail_ptr); 1214 txdata->mid = vif->mid; 1215 txdata->enabled = 1; 1216 spin_unlock_bh(&txdata->lock); 1217 1218 if (txdata->dot1x_open && (agg_wsize >= 0)) 1219 wil_addba_tx_request(wil, id, agg_wsize); 1220 1221 return 0; 1222 out_free: 1223 spin_lock_bh(&txdata->lock); 1224 txdata->dot1x_open = false; 1225 txdata->enabled = 0; 1226 spin_unlock_bh(&txdata->lock); 1227 wil_vring_free(wil, vring); 1228 wil->ring2cid_tid[id][0] = wil->max_assoc_sta; 1229 wil->ring2cid_tid[id][1] = 0; 1230 1231 out: 1232 1233 return rc; 1234 } 1235 1236 static int wil_tx_vring_modify(struct wil6210_vif *vif, int ring_id, int cid, 1237 int tid) 1238 { 1239 struct wil6210_priv *wil = vif_to_wil(vif); 1240 int rc; 1241 struct wmi_vring_cfg_cmd cmd = { 1242 .action = cpu_to_le32(WMI_VRING_CMD_MODIFY), 1243 .vring_cfg = { 1244 .tx_sw_ring = { 1245 .max_mpdu_size = 1246 cpu_to_le16(wil_mtu2macbuf(mtu_max)), 1247 .ring_size = 0, 1248 }, 1249 .ringid = ring_id, 1250 .cidxtid = mk_cidxtid(cid, tid), 1251 .encap_trans_type = WMI_VRING_ENC_TYPE_802_3, 1252 .mac_ctrl = 0, 1253 .to_resolution = 0, 1254 .agg_max_wsize = 0, 1255 .schd_params = { 1256 .priority = cpu_to_le16(0), 1257 .timeslot_us = cpu_to_le16(0xfff), 1258 }, 1259 }, 1260 }; 1261 struct { 1262 struct wmi_cmd_hdr wmi; 1263 struct wmi_vring_cfg_done_event cmd; 1264 } __packed reply = { 1265 .cmd = {.status = WMI_FW_STATUS_FAILURE}, 1266 }; 1267 struct wil_ring *vring = &wil->ring_tx[ring_id]; 1268 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[ring_id]; 1269 1270 wil_dbg_misc(wil, "vring_modify: ring %d cid %d tid %d\n", ring_id, 1271 cid, tid); 1272 lockdep_assert_held(&wil->mutex); 1273 1274 if (!vring->va) { 1275 wil_err(wil, "Tx ring [%d] not allocated\n", ring_id); 1276 return -EINVAL; 1277 } 1278 1279 if (wil->ring2cid_tid[ring_id][0] != cid || 1280 wil->ring2cid_tid[ring_id][1] != tid) { 1281 wil_err(wil, "ring info does not match cid=%u tid=%u\n", 1282 wil->ring2cid_tid[ring_id][0], 1283 wil->ring2cid_tid[ring_id][1]); 1284 } 1285 1286 cmd.vring_cfg.tx_sw_ring.ring_mem_base = cpu_to_le64(vring->pa); 1287 1288 rc = wmi_call(wil, WMI_VRING_CFG_CMDID, vif->mid, &cmd, sizeof(cmd), 1289 WMI_VRING_CFG_DONE_EVENTID, &reply, sizeof(reply), 1290 WIL_WMI_CALL_GENERAL_TO_MS); 1291 if (rc) 1292 goto fail; 1293 1294 if (reply.cmd.status != WMI_FW_STATUS_SUCCESS) { 1295 wil_err(wil, "Tx modify failed, status 0x%02x\n", 1296 reply.cmd.status); 1297 rc = -EINVAL; 1298 goto fail; 1299 } 1300 1301 /* set BA aggregation window size to 0 to force a new BA with the 1302 * new AP 1303 */ 1304 txdata->agg_wsize = 0; 1305 if (txdata->dot1x_open && agg_wsize >= 0) 1306 wil_addba_tx_request(wil, ring_id, agg_wsize); 1307 1308 return 0; 1309 fail: 1310 spin_lock_bh(&txdata->lock); 1311 txdata->dot1x_open = false; 1312 txdata->enabled = 0; 1313 spin_unlock_bh(&txdata->lock); 1314 wil->ring2cid_tid[ring_id][0] = wil->max_assoc_sta; 1315 wil->ring2cid_tid[ring_id][1] = 0; 1316 return rc; 1317 } 1318 1319 int wil_vring_init_bcast(struct wil6210_vif *vif, int id, int size) 1320 { 1321 struct wil6210_priv *wil = vif_to_wil(vif); 1322 int rc; 1323 struct wmi_bcast_vring_cfg_cmd cmd = { 1324 .action = cpu_to_le32(WMI_VRING_CMD_ADD), 1325 .vring_cfg = { 1326 .tx_sw_ring = { 1327 .max_mpdu_size = 1328 cpu_to_le16(wil_mtu2macbuf(mtu_max)), 1329 .ring_size = cpu_to_le16(size), 1330 }, 1331 .ringid = id, 1332 .encap_trans_type = WMI_VRING_ENC_TYPE_802_3, 1333 }, 1334 }; 1335 struct { 1336 struct wmi_cmd_hdr wmi; 1337 struct wmi_vring_cfg_done_event cmd; 1338 } __packed reply = { 1339 .cmd = {.status = WMI_FW_STATUS_FAILURE}, 1340 }; 1341 struct wil_ring *vring = &wil->ring_tx[id]; 1342 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[id]; 1343 1344 wil_dbg_misc(wil, "vring_init_bcast: max_mpdu_size %d\n", 1345 cmd.vring_cfg.tx_sw_ring.max_mpdu_size); 1346 lockdep_assert_held(&wil->mutex); 1347 1348 if (vring->va) { 1349 wil_err(wil, "Tx ring [%d] already allocated\n", id); 1350 rc = -EINVAL; 1351 goto out; 1352 } 1353 1354 wil_tx_data_init(txdata); 1355 vring->is_rx = false; 1356 vring->size = size; 1357 rc = wil_vring_alloc(wil, vring); 1358 if (rc) 1359 goto out; 1360 1361 wil->ring2cid_tid[id][0] = wil->max_assoc_sta; /* CID */ 1362 wil->ring2cid_tid[id][1] = 0; /* TID */ 1363 1364 cmd.vring_cfg.tx_sw_ring.ring_mem_base = cpu_to_le64(vring->pa); 1365 1366 if (!vif->privacy) 1367 txdata->dot1x_open = true; 1368 rc = wmi_call(wil, WMI_BCAST_VRING_CFG_CMDID, vif->mid, 1369 &cmd, sizeof(cmd), 1370 WMI_VRING_CFG_DONE_EVENTID, &reply, sizeof(reply), 1371 WIL_WMI_CALL_GENERAL_TO_MS); 1372 if (rc) 1373 goto out_free; 1374 1375 if (reply.cmd.status != WMI_FW_STATUS_SUCCESS) { 1376 wil_err(wil, "Tx config failed, status 0x%02x\n", 1377 reply.cmd.status); 1378 rc = -EINVAL; 1379 goto out_free; 1380 } 1381 1382 spin_lock_bh(&txdata->lock); 1383 vring->hwtail = le32_to_cpu(reply.cmd.tx_vring_tail_ptr); 1384 txdata->mid = vif->mid; 1385 txdata->enabled = 1; 1386 spin_unlock_bh(&txdata->lock); 1387 1388 return 0; 1389 out_free: 1390 spin_lock_bh(&txdata->lock); 1391 txdata->enabled = 0; 1392 txdata->dot1x_open = false; 1393 spin_unlock_bh(&txdata->lock); 1394 wil_vring_free(wil, vring); 1395 out: 1396 1397 return rc; 1398 } 1399 1400 static struct wil_ring *wil_find_tx_ucast(struct wil6210_priv *wil, 1401 struct wil6210_vif *vif, 1402 struct sk_buff *skb) 1403 { 1404 int i, cid; 1405 const u8 *da = wil_skb_get_da(skb); 1406 int min_ring_id = wil_get_min_tx_ring_id(wil); 1407 1408 cid = wil_find_cid(wil, vif->mid, da); 1409 1410 if (cid < 0 || cid >= wil->max_assoc_sta) 1411 return NULL; 1412 1413 /* TODO: fix for multiple TID */ 1414 for (i = min_ring_id; i < ARRAY_SIZE(wil->ring2cid_tid); i++) { 1415 if (!wil->ring_tx_data[i].dot1x_open && 1416 skb->protocol != cpu_to_be16(ETH_P_PAE)) 1417 continue; 1418 if (wil->ring2cid_tid[i][0] == cid) { 1419 struct wil_ring *v = &wil->ring_tx[i]; 1420 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[i]; 1421 1422 wil_dbg_txrx(wil, "find_tx_ucast: (%pM) -> [%d]\n", 1423 da, i); 1424 if (v->va && txdata->enabled) { 1425 return v; 1426 } else { 1427 wil_dbg_txrx(wil, 1428 "find_tx_ucast: vring[%d] not valid\n", 1429 i); 1430 return NULL; 1431 } 1432 } 1433 } 1434 1435 return NULL; 1436 } 1437 1438 static int wil_tx_ring(struct wil6210_priv *wil, struct wil6210_vif *vif, 1439 struct wil_ring *ring, struct sk_buff *skb); 1440 1441 static struct wil_ring *wil_find_tx_ring_sta(struct wil6210_priv *wil, 1442 struct wil6210_vif *vif, 1443 struct sk_buff *skb) 1444 { 1445 struct wil_ring *ring; 1446 int i; 1447 u8 cid; 1448 struct wil_ring_tx_data *txdata; 1449 int min_ring_id = wil_get_min_tx_ring_id(wil); 1450 1451 /* In the STA mode, it is expected to have only 1 VRING 1452 * for the AP we connected to. 1453 * find 1-st vring eligible for this skb and use it. 1454 */ 1455 for (i = min_ring_id; i < WIL6210_MAX_TX_RINGS; i++) { 1456 ring = &wil->ring_tx[i]; 1457 txdata = &wil->ring_tx_data[i]; 1458 if (!ring->va || !txdata->enabled || txdata->mid != vif->mid) 1459 continue; 1460 1461 cid = wil->ring2cid_tid[i][0]; 1462 if (cid >= wil->max_assoc_sta) /* skip BCAST */ 1463 continue; 1464 1465 if (!wil->ring_tx_data[i].dot1x_open && 1466 skb->protocol != cpu_to_be16(ETH_P_PAE)) 1467 continue; 1468 1469 wil_dbg_txrx(wil, "Tx -> ring %d\n", i); 1470 1471 return ring; 1472 } 1473 1474 wil_dbg_txrx(wil, "Tx while no rings active?\n"); 1475 1476 return NULL; 1477 } 1478 1479 /* Use one of 2 strategies: 1480 * 1481 * 1. New (real broadcast): 1482 * use dedicated broadcast vring 1483 * 2. Old (pseudo-DMS): 1484 * Find 1-st vring and return it; 1485 * duplicate skb and send it to other active vrings; 1486 * in all cases override dest address to unicast peer's address 1487 * Use old strategy when new is not supported yet: 1488 * - for PBSS 1489 */ 1490 static struct wil_ring *wil_find_tx_bcast_1(struct wil6210_priv *wil, 1491 struct wil6210_vif *vif, 1492 struct sk_buff *skb) 1493 { 1494 struct wil_ring *v; 1495 struct wil_ring_tx_data *txdata; 1496 int i = vif->bcast_ring; 1497 1498 if (i < 0) 1499 return NULL; 1500 v = &wil->ring_tx[i]; 1501 txdata = &wil->ring_tx_data[i]; 1502 if (!v->va || !txdata->enabled) 1503 return NULL; 1504 if (!wil->ring_tx_data[i].dot1x_open && 1505 skb->protocol != cpu_to_be16(ETH_P_PAE)) 1506 return NULL; 1507 1508 return v; 1509 } 1510 1511 /* apply multicast to unicast only for ARP and IP packets 1512 * (see NL80211_CMD_SET_MULTICAST_TO_UNICAST for more info) 1513 */ 1514 static bool wil_check_multicast_to_unicast(struct wil6210_priv *wil, 1515 struct sk_buff *skb) 1516 { 1517 const struct ethhdr *eth = (void *)skb->data; 1518 const struct vlan_ethhdr *ethvlan = (void *)skb->data; 1519 __be16 ethertype; 1520 1521 if (!wil->multicast_to_unicast) 1522 return false; 1523 1524 /* multicast to unicast conversion only for some payload */ 1525 ethertype = eth->h_proto; 1526 if (ethertype == htons(ETH_P_8021Q) && skb->len >= VLAN_ETH_HLEN) 1527 ethertype = ethvlan->h_vlan_encapsulated_proto; 1528 switch (ethertype) { 1529 case htons(ETH_P_ARP): 1530 case htons(ETH_P_IP): 1531 case htons(ETH_P_IPV6): 1532 break; 1533 default: 1534 return false; 1535 } 1536 1537 return true; 1538 } 1539 1540 static void wil_set_da_for_vring(struct wil6210_priv *wil, 1541 struct sk_buff *skb, int vring_index) 1542 { 1543 u8 *da = wil_skb_get_da(skb); 1544 int cid = wil->ring2cid_tid[vring_index][0]; 1545 1546 ether_addr_copy(da, wil->sta[cid].addr); 1547 } 1548 1549 static struct wil_ring *wil_find_tx_bcast_2(struct wil6210_priv *wil, 1550 struct wil6210_vif *vif, 1551 struct sk_buff *skb) 1552 { 1553 struct wil_ring *v, *v2; 1554 struct sk_buff *skb2; 1555 int i; 1556 u8 cid; 1557 const u8 *src = wil_skb_get_sa(skb); 1558 struct wil_ring_tx_data *txdata, *txdata2; 1559 int min_ring_id = wil_get_min_tx_ring_id(wil); 1560 1561 /* find 1-st vring eligible for data */ 1562 for (i = min_ring_id; i < WIL6210_MAX_TX_RINGS; i++) { 1563 v = &wil->ring_tx[i]; 1564 txdata = &wil->ring_tx_data[i]; 1565 if (!v->va || !txdata->enabled || txdata->mid != vif->mid) 1566 continue; 1567 1568 cid = wil->ring2cid_tid[i][0]; 1569 if (cid >= wil->max_assoc_sta) /* skip BCAST */ 1570 continue; 1571 if (!wil->ring_tx_data[i].dot1x_open && 1572 skb->protocol != cpu_to_be16(ETH_P_PAE)) 1573 continue; 1574 1575 /* don't Tx back to source when re-routing Rx->Tx at the AP */ 1576 if (0 == memcmp(wil->sta[cid].addr, src, ETH_ALEN)) 1577 continue; 1578 1579 goto found; 1580 } 1581 1582 wil_dbg_txrx(wil, "Tx while no vrings active?\n"); 1583 1584 return NULL; 1585 1586 found: 1587 wil_dbg_txrx(wil, "BCAST -> ring %d\n", i); 1588 wil_set_da_for_vring(wil, skb, i); 1589 1590 /* find other active vrings and duplicate skb for each */ 1591 for (i++; i < WIL6210_MAX_TX_RINGS; i++) { 1592 v2 = &wil->ring_tx[i]; 1593 txdata2 = &wil->ring_tx_data[i]; 1594 if (!v2->va || txdata2->mid != vif->mid) 1595 continue; 1596 cid = wil->ring2cid_tid[i][0]; 1597 if (cid >= wil->max_assoc_sta) /* skip BCAST */ 1598 continue; 1599 if (!wil->ring_tx_data[i].dot1x_open && 1600 skb->protocol != cpu_to_be16(ETH_P_PAE)) 1601 continue; 1602 1603 if (0 == memcmp(wil->sta[cid].addr, src, ETH_ALEN)) 1604 continue; 1605 1606 skb2 = skb_copy(skb, GFP_ATOMIC); 1607 if (skb2) { 1608 wil_dbg_txrx(wil, "BCAST DUP -> ring %d\n", i); 1609 wil_set_da_for_vring(wil, skb2, i); 1610 wil_tx_ring(wil, vif, v2, skb2); 1611 /* successful call to wil_tx_ring takes skb2 ref */ 1612 dev_kfree_skb_any(skb2); 1613 } else { 1614 wil_err(wil, "skb_copy failed\n"); 1615 } 1616 } 1617 1618 return v; 1619 } 1620 1621 static inline 1622 void wil_tx_desc_set_nr_frags(struct vring_tx_desc *d, int nr_frags) 1623 { 1624 d->mac.d[2] |= (nr_frags << MAC_CFG_DESC_TX_2_NUM_OF_DESCRIPTORS_POS); 1625 } 1626 1627 /* Sets the descriptor @d up for csum and/or TSO offloading. The corresponding 1628 * @skb is used to obtain the protocol and headers length. 1629 * @tso_desc_type is a descriptor type for TSO: 0 - a header, 1 - first data, 1630 * 2 - middle, 3 - last descriptor. 1631 */ 1632 1633 static void wil_tx_desc_offload_setup_tso(struct vring_tx_desc *d, 1634 struct sk_buff *skb, 1635 int tso_desc_type, bool is_ipv4, 1636 int tcp_hdr_len, int skb_net_hdr_len) 1637 { 1638 d->dma.b11 = ETH_HLEN; /* MAC header length */ 1639 d->dma.b11 |= is_ipv4 << DMA_CFG_DESC_TX_OFFLOAD_CFG_L3T_IPV4_POS; 1640 1641 d->dma.d0 |= (2 << DMA_CFG_DESC_TX_0_L4_TYPE_POS); 1642 /* L4 header len: TCP header length */ 1643 d->dma.d0 |= (tcp_hdr_len & DMA_CFG_DESC_TX_0_L4_LENGTH_MSK); 1644 1645 /* Setup TSO: bit and desc type */ 1646 d->dma.d0 |= (BIT(DMA_CFG_DESC_TX_0_TCP_SEG_EN_POS)) | 1647 (tso_desc_type << DMA_CFG_DESC_TX_0_SEGMENT_BUF_DETAILS_POS); 1648 d->dma.d0 |= (is_ipv4 << DMA_CFG_DESC_TX_0_IPV4_CHECKSUM_EN_POS); 1649 1650 d->dma.ip_length = skb_net_hdr_len; 1651 /* Enable TCP/UDP checksum */ 1652 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_TCP_UDP_CHECKSUM_EN_POS); 1653 /* Calculate pseudo-header */ 1654 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_PSEUDO_HEADER_CALC_EN_POS); 1655 } 1656 1657 /* Sets the descriptor @d up for csum. The corresponding 1658 * @skb is used to obtain the protocol and headers length. 1659 * Returns the protocol: 0 - not TCP, 1 - TCPv4, 2 - TCPv6. 1660 * Note, if d==NULL, the function only returns the protocol result. 1661 * 1662 * It is very similar to previous wil_tx_desc_offload_setup_tso. This 1663 * is "if unrolling" to optimize the critical path. 1664 */ 1665 1666 static int wil_tx_desc_offload_setup(struct vring_tx_desc *d, 1667 struct sk_buff *skb){ 1668 int protocol; 1669 1670 if (skb->ip_summed != CHECKSUM_PARTIAL) 1671 return 0; 1672 1673 d->dma.b11 = ETH_HLEN; /* MAC header length */ 1674 1675 switch (skb->protocol) { 1676 case cpu_to_be16(ETH_P_IP): 1677 protocol = ip_hdr(skb)->protocol; 1678 d->dma.b11 |= BIT(DMA_CFG_DESC_TX_OFFLOAD_CFG_L3T_IPV4_POS); 1679 break; 1680 case cpu_to_be16(ETH_P_IPV6): 1681 protocol = ipv6_hdr(skb)->nexthdr; 1682 break; 1683 default: 1684 return -EINVAL; 1685 } 1686 1687 switch (protocol) { 1688 case IPPROTO_TCP: 1689 d->dma.d0 |= (2 << DMA_CFG_DESC_TX_0_L4_TYPE_POS); 1690 /* L4 header len: TCP header length */ 1691 d->dma.d0 |= 1692 (tcp_hdrlen(skb) & DMA_CFG_DESC_TX_0_L4_LENGTH_MSK); 1693 break; 1694 case IPPROTO_UDP: 1695 /* L4 header len: UDP header length */ 1696 d->dma.d0 |= 1697 (sizeof(struct udphdr) & DMA_CFG_DESC_TX_0_L4_LENGTH_MSK); 1698 break; 1699 default: 1700 return -EINVAL; 1701 } 1702 1703 d->dma.ip_length = skb_network_header_len(skb); 1704 /* Enable TCP/UDP checksum */ 1705 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_TCP_UDP_CHECKSUM_EN_POS); 1706 /* Calculate pseudo-header */ 1707 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_PSEUDO_HEADER_CALC_EN_POS); 1708 1709 return 0; 1710 } 1711 1712 static inline void wil_tx_last_desc(struct vring_tx_desc *d) 1713 { 1714 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_CMD_EOP_POS) | 1715 BIT(DMA_CFG_DESC_TX_0_CMD_MARK_WB_POS) | 1716 BIT(DMA_CFG_DESC_TX_0_CMD_DMA_IT_POS); 1717 } 1718 1719 static inline void wil_set_tx_desc_last_tso(volatile struct vring_tx_desc *d) 1720 { 1721 d->dma.d0 |= wil_tso_type_lst << 1722 DMA_CFG_DESC_TX_0_SEGMENT_BUF_DETAILS_POS; 1723 } 1724 1725 static int __wil_tx_vring_tso(struct wil6210_priv *wil, struct wil6210_vif *vif, 1726 struct wil_ring *vring, struct sk_buff *skb) 1727 { 1728 struct device *dev = wil_to_dev(wil); 1729 1730 /* point to descriptors in shared memory */ 1731 volatile struct vring_tx_desc *_desc = NULL, *_hdr_desc, 1732 *_first_desc = NULL; 1733 1734 /* pointers to shadow descriptors */ 1735 struct vring_tx_desc desc_mem, hdr_desc_mem, first_desc_mem, 1736 *d = &hdr_desc_mem, *hdr_desc = &hdr_desc_mem, 1737 *first_desc = &first_desc_mem; 1738 1739 /* pointer to shadow descriptors' context */ 1740 struct wil_ctx *hdr_ctx, *first_ctx = NULL; 1741 1742 int descs_used = 0; /* total number of used descriptors */ 1743 int sg_desc_cnt = 0; /* number of descriptors for current mss*/ 1744 1745 u32 swhead = vring->swhead; 1746 int used, avail = wil_ring_avail_tx(vring); 1747 int nr_frags = skb_shinfo(skb)->nr_frags; 1748 int min_desc_required = nr_frags + 1; 1749 int mss = skb_shinfo(skb)->gso_size; /* payload size w/o headers */ 1750 int f, len, hdrlen, headlen; 1751 int vring_index = vring - wil->ring_tx; 1752 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[vring_index]; 1753 uint i = swhead; 1754 dma_addr_t pa; 1755 const skb_frag_t *frag = NULL; 1756 int rem_data = mss; 1757 int lenmss; 1758 int hdr_compensation_need = true; 1759 int desc_tso_type = wil_tso_type_first; 1760 bool is_ipv4; 1761 int tcp_hdr_len; 1762 int skb_net_hdr_len; 1763 int gso_type; 1764 int rc = -EINVAL; 1765 1766 wil_dbg_txrx(wil, "tx_vring_tso: %d bytes to vring %d\n", skb->len, 1767 vring_index); 1768 1769 if (unlikely(!txdata->enabled)) 1770 return -EINVAL; 1771 1772 /* A typical page 4K is 3-4 payloads, we assume each fragment 1773 * is a full payload, that's how min_desc_required has been 1774 * calculated. In real we might need more or less descriptors, 1775 * this is the initial check only. 1776 */ 1777 if (unlikely(avail < min_desc_required)) { 1778 wil_err_ratelimited(wil, 1779 "TSO: Tx ring[%2d] full. No space for %d fragments\n", 1780 vring_index, min_desc_required); 1781 return -ENOMEM; 1782 } 1783 1784 /* Header Length = MAC header len + IP header len + TCP header len*/ 1785 hdrlen = ETH_HLEN + 1786 (int)skb_network_header_len(skb) + 1787 tcp_hdrlen(skb); 1788 1789 gso_type = skb_shinfo(skb)->gso_type & (SKB_GSO_TCPV6 | SKB_GSO_TCPV4); 1790 switch (gso_type) { 1791 case SKB_GSO_TCPV4: 1792 /* TCP v4, zero out the IP length and IPv4 checksum fields 1793 * as required by the offloading doc 1794 */ 1795 ip_hdr(skb)->tot_len = 0; 1796 ip_hdr(skb)->check = 0; 1797 is_ipv4 = true; 1798 break; 1799 case SKB_GSO_TCPV6: 1800 /* TCP v6, zero out the payload length */ 1801 ipv6_hdr(skb)->payload_len = 0; 1802 is_ipv4 = false; 1803 break; 1804 default: 1805 /* other than TCPv4 or TCPv6 types are not supported for TSO. 1806 * It is also illegal for both to be set simultaneously 1807 */ 1808 return -EINVAL; 1809 } 1810 1811 if (skb->ip_summed != CHECKSUM_PARTIAL) 1812 return -EINVAL; 1813 1814 /* tcp header length and skb network header length are fixed for all 1815 * packet's descriptors - read then once here 1816 */ 1817 tcp_hdr_len = tcp_hdrlen(skb); 1818 skb_net_hdr_len = skb_network_header_len(skb); 1819 1820 _hdr_desc = &vring->va[i].tx.legacy; 1821 1822 pa = dma_map_single(dev, skb->data, hdrlen, DMA_TO_DEVICE); 1823 if (unlikely(dma_mapping_error(dev, pa))) { 1824 wil_err(wil, "TSO: Skb head DMA map error\n"); 1825 goto err_exit; 1826 } 1827 1828 wil->txrx_ops.tx_desc_map((union wil_tx_desc *)hdr_desc, pa, 1829 hdrlen, vring_index); 1830 wil_tx_desc_offload_setup_tso(hdr_desc, skb, wil_tso_type_hdr, is_ipv4, 1831 tcp_hdr_len, skb_net_hdr_len); 1832 wil_tx_last_desc(hdr_desc); 1833 1834 vring->ctx[i].mapped_as = wil_mapped_as_single; 1835 hdr_ctx = &vring->ctx[i]; 1836 1837 descs_used++; 1838 headlen = skb_headlen(skb) - hdrlen; 1839 1840 for (f = headlen ? -1 : 0; f < nr_frags; f++) { 1841 if (headlen) { 1842 len = headlen; 1843 wil_dbg_txrx(wil, "TSO: process skb head, len %u\n", 1844 len); 1845 } else { 1846 frag = &skb_shinfo(skb)->frags[f]; 1847 len = skb_frag_size(frag); 1848 wil_dbg_txrx(wil, "TSO: frag[%d]: len %u\n", f, len); 1849 } 1850 1851 while (len) { 1852 wil_dbg_txrx(wil, 1853 "TSO: len %d, rem_data %d, descs_used %d\n", 1854 len, rem_data, descs_used); 1855 1856 if (descs_used == avail) { 1857 wil_err_ratelimited(wil, "TSO: ring overflow\n"); 1858 rc = -ENOMEM; 1859 goto mem_error; 1860 } 1861 1862 lenmss = min_t(int, rem_data, len); 1863 i = (swhead + descs_used) % vring->size; 1864 wil_dbg_txrx(wil, "TSO: lenmss %d, i %d\n", lenmss, i); 1865 1866 if (!headlen) { 1867 pa = skb_frag_dma_map(dev, frag, 1868 skb_frag_size(frag) - len, 1869 lenmss, DMA_TO_DEVICE); 1870 vring->ctx[i].mapped_as = wil_mapped_as_page; 1871 } else { 1872 pa = dma_map_single(dev, 1873 skb->data + 1874 skb_headlen(skb) - headlen, 1875 lenmss, 1876 DMA_TO_DEVICE); 1877 vring->ctx[i].mapped_as = wil_mapped_as_single; 1878 headlen -= lenmss; 1879 } 1880 1881 if (unlikely(dma_mapping_error(dev, pa))) { 1882 wil_err(wil, "TSO: DMA map page error\n"); 1883 goto mem_error; 1884 } 1885 1886 _desc = &vring->va[i].tx.legacy; 1887 1888 if (!_first_desc) { 1889 _first_desc = _desc; 1890 first_ctx = &vring->ctx[i]; 1891 d = first_desc; 1892 } else { 1893 d = &desc_mem; 1894 } 1895 1896 wil->txrx_ops.tx_desc_map((union wil_tx_desc *)d, 1897 pa, lenmss, vring_index); 1898 wil_tx_desc_offload_setup_tso(d, skb, desc_tso_type, 1899 is_ipv4, tcp_hdr_len, 1900 skb_net_hdr_len); 1901 1902 /* use tso_type_first only once */ 1903 desc_tso_type = wil_tso_type_mid; 1904 1905 descs_used++; /* desc used so far */ 1906 sg_desc_cnt++; /* desc used for this segment */ 1907 len -= lenmss; 1908 rem_data -= lenmss; 1909 1910 wil_dbg_txrx(wil, 1911 "TSO: len %d, rem_data %d, descs_used %d, sg_desc_cnt %d,\n", 1912 len, rem_data, descs_used, sg_desc_cnt); 1913 1914 /* Close the segment if reached mss size or last frag*/ 1915 if (rem_data == 0 || (f == nr_frags - 1 && len == 0)) { 1916 if (hdr_compensation_need) { 1917 /* first segment include hdr desc for 1918 * release 1919 */ 1920 hdr_ctx->nr_frags = sg_desc_cnt; 1921 wil_tx_desc_set_nr_frags(first_desc, 1922 sg_desc_cnt + 1923 1); 1924 hdr_compensation_need = false; 1925 } else { 1926 wil_tx_desc_set_nr_frags(first_desc, 1927 sg_desc_cnt); 1928 } 1929 first_ctx->nr_frags = sg_desc_cnt - 1; 1930 1931 wil_tx_last_desc(d); 1932 1933 /* first descriptor may also be the last 1934 * for this mss - make sure not to copy 1935 * it twice 1936 */ 1937 if (first_desc != d) 1938 *_first_desc = *first_desc; 1939 1940 /*last descriptor will be copied at the end 1941 * of this TS processing 1942 */ 1943 if (f < nr_frags - 1 || len > 0) 1944 *_desc = *d; 1945 1946 rem_data = mss; 1947 _first_desc = NULL; 1948 sg_desc_cnt = 0; 1949 } else if (first_desc != d) /* update mid descriptor */ 1950 *_desc = *d; 1951 } 1952 } 1953 1954 if (!_desc) 1955 goto mem_error; 1956 1957 /* first descriptor may also be the last. 1958 * in this case d pointer is invalid 1959 */ 1960 if (_first_desc == _desc) 1961 d = first_desc; 1962 1963 /* Last data descriptor */ 1964 wil_set_tx_desc_last_tso(d); 1965 *_desc = *d; 1966 1967 /* Fill the total number of descriptors in first desc (hdr)*/ 1968 wil_tx_desc_set_nr_frags(hdr_desc, descs_used); 1969 *_hdr_desc = *hdr_desc; 1970 1971 /* hold reference to skb 1972 * to prevent skb release before accounting 1973 * in case of immediate "tx done" 1974 */ 1975 vring->ctx[i].skb = skb_get(skb); 1976 1977 /* performance monitoring */ 1978 used = wil_ring_used_tx(vring); 1979 if (wil_val_in_range(wil->ring_idle_trsh, 1980 used, used + descs_used)) { 1981 txdata->idle += get_cycles() - txdata->last_idle; 1982 wil_dbg_txrx(wil, "Ring[%2d] not idle %d -> %d\n", 1983 vring_index, used, used + descs_used); 1984 } 1985 1986 /* Make sure to advance the head only after descriptor update is done. 1987 * This will prevent a race condition where the completion thread 1988 * will see the DU bit set from previous run and will handle the 1989 * skb before it was completed. 1990 */ 1991 wmb(); 1992 1993 /* advance swhead */ 1994 wil_ring_advance_head(vring, descs_used); 1995 wil_dbg_txrx(wil, "TSO: Tx swhead %d -> %d\n", swhead, vring->swhead); 1996 1997 /* make sure all writes to descriptors (shared memory) are done before 1998 * committing them to HW 1999 */ 2000 wmb(); 2001 2002 if (wil->tx_latency) 2003 *(ktime_t *)&skb->cb = ktime_get(); 2004 else 2005 memset(skb->cb, 0, sizeof(ktime_t)); 2006 2007 wil_w(wil, vring->hwtail, vring->swhead); 2008 return 0; 2009 2010 mem_error: 2011 while (descs_used > 0) { 2012 struct wil_ctx *ctx; 2013 2014 i = (swhead + descs_used - 1) % vring->size; 2015 d = (struct vring_tx_desc *)&vring->va[i].tx.legacy; 2016 _desc = &vring->va[i].tx.legacy; 2017 *d = *_desc; 2018 _desc->dma.status = TX_DMA_STATUS_DU; 2019 ctx = &vring->ctx[i]; 2020 wil_txdesc_unmap(dev, (union wil_tx_desc *)d, ctx); 2021 memset(ctx, 0, sizeof(*ctx)); 2022 descs_used--; 2023 } 2024 err_exit: 2025 return rc; 2026 } 2027 2028 static int __wil_tx_ring(struct wil6210_priv *wil, struct wil6210_vif *vif, 2029 struct wil_ring *ring, struct sk_buff *skb) 2030 { 2031 struct device *dev = wil_to_dev(wil); 2032 struct vring_tx_desc dd, *d = ⅆ 2033 volatile struct vring_tx_desc *_d; 2034 u32 swhead = ring->swhead; 2035 int avail = wil_ring_avail_tx(ring); 2036 int nr_frags = skb_shinfo(skb)->nr_frags; 2037 uint f = 0; 2038 int ring_index = ring - wil->ring_tx; 2039 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[ring_index]; 2040 uint i = swhead; 2041 dma_addr_t pa; 2042 int used; 2043 bool mcast = (ring_index == vif->bcast_ring); 2044 uint len = skb_headlen(skb); 2045 2046 wil_dbg_txrx(wil, "tx_ring: %d bytes to ring %d, nr_frags %d\n", 2047 skb->len, ring_index, nr_frags); 2048 2049 if (unlikely(!txdata->enabled)) 2050 return -EINVAL; 2051 2052 if (unlikely(avail < 1 + nr_frags)) { 2053 wil_err_ratelimited(wil, 2054 "Tx ring[%2d] full. No space for %d fragments\n", 2055 ring_index, 1 + nr_frags); 2056 return -ENOMEM; 2057 } 2058 _d = &ring->va[i].tx.legacy; 2059 2060 pa = dma_map_single(dev, skb->data, skb_headlen(skb), DMA_TO_DEVICE); 2061 2062 wil_dbg_txrx(wil, "Tx[%2d] skb %d bytes 0x%p -> %pad\n", ring_index, 2063 skb_headlen(skb), skb->data, &pa); 2064 wil_hex_dump_txrx("Tx ", DUMP_PREFIX_OFFSET, 16, 1, 2065 skb->data, skb_headlen(skb), false); 2066 2067 if (unlikely(dma_mapping_error(dev, pa))) 2068 return -EINVAL; 2069 ring->ctx[i].mapped_as = wil_mapped_as_single; 2070 /* 1-st segment */ 2071 wil->txrx_ops.tx_desc_map((union wil_tx_desc *)d, pa, len, 2072 ring_index); 2073 if (unlikely(mcast)) { 2074 d->mac.d[0] |= BIT(MAC_CFG_DESC_TX_0_MCS_EN_POS); /* MCS 0 */ 2075 if (unlikely(len > WIL_BCAST_MCS0_LIMIT)) /* set MCS 1 */ 2076 d->mac.d[0] |= (1 << MAC_CFG_DESC_TX_0_MCS_INDEX_POS); 2077 } 2078 /* Process TCP/UDP checksum offloading */ 2079 if (unlikely(wil_tx_desc_offload_setup(d, skb))) { 2080 wil_err(wil, "Tx[%2d] Failed to set cksum, drop packet\n", 2081 ring_index); 2082 goto dma_error; 2083 } 2084 2085 ring->ctx[i].nr_frags = nr_frags; 2086 wil_tx_desc_set_nr_frags(d, nr_frags + 1); 2087 2088 /* middle segments */ 2089 for (; f < nr_frags; f++) { 2090 const skb_frag_t *frag = &skb_shinfo(skb)->frags[f]; 2091 int len = skb_frag_size(frag); 2092 2093 *_d = *d; 2094 wil_dbg_txrx(wil, "Tx[%2d] desc[%4d]\n", ring_index, i); 2095 wil_hex_dump_txrx("TxD ", DUMP_PREFIX_NONE, 32, 4, 2096 (const void *)d, sizeof(*d), false); 2097 i = (swhead + f + 1) % ring->size; 2098 _d = &ring->va[i].tx.legacy; 2099 pa = skb_frag_dma_map(dev, frag, 0, skb_frag_size(frag), 2100 DMA_TO_DEVICE); 2101 if (unlikely(dma_mapping_error(dev, pa))) { 2102 wil_err(wil, "Tx[%2d] failed to map fragment\n", 2103 ring_index); 2104 goto dma_error; 2105 } 2106 ring->ctx[i].mapped_as = wil_mapped_as_page; 2107 wil->txrx_ops.tx_desc_map((union wil_tx_desc *)d, 2108 pa, len, ring_index); 2109 /* no need to check return code - 2110 * if it succeeded for 1-st descriptor, 2111 * it will succeed here too 2112 */ 2113 wil_tx_desc_offload_setup(d, skb); 2114 } 2115 /* for the last seg only */ 2116 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_CMD_EOP_POS); 2117 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_CMD_MARK_WB_POS); 2118 d->dma.d0 |= BIT(DMA_CFG_DESC_TX_0_CMD_DMA_IT_POS); 2119 *_d = *d; 2120 wil_dbg_txrx(wil, "Tx[%2d] desc[%4d]\n", ring_index, i); 2121 wil_hex_dump_txrx("TxD ", DUMP_PREFIX_NONE, 32, 4, 2122 (const void *)d, sizeof(*d), false); 2123 2124 /* hold reference to skb 2125 * to prevent skb release before accounting 2126 * in case of immediate "tx done" 2127 */ 2128 ring->ctx[i].skb = skb_get(skb); 2129 2130 /* performance monitoring */ 2131 used = wil_ring_used_tx(ring); 2132 if (wil_val_in_range(wil->ring_idle_trsh, 2133 used, used + nr_frags + 1)) { 2134 txdata->idle += get_cycles() - txdata->last_idle; 2135 wil_dbg_txrx(wil, "Ring[%2d] not idle %d -> %d\n", 2136 ring_index, used, used + nr_frags + 1); 2137 } 2138 2139 /* Make sure to advance the head only after descriptor update is done. 2140 * This will prevent a race condition where the completion thread 2141 * will see the DU bit set from previous run and will handle the 2142 * skb before it was completed. 2143 */ 2144 wmb(); 2145 2146 /* advance swhead */ 2147 wil_ring_advance_head(ring, nr_frags + 1); 2148 wil_dbg_txrx(wil, "Tx[%2d] swhead %d -> %d\n", ring_index, swhead, 2149 ring->swhead); 2150 trace_wil6210_tx(ring_index, swhead, skb->len, nr_frags); 2151 2152 /* make sure all writes to descriptors (shared memory) are done before 2153 * committing them to HW 2154 */ 2155 wmb(); 2156 2157 if (wil->tx_latency) 2158 *(ktime_t *)&skb->cb = ktime_get(); 2159 else 2160 memset(skb->cb, 0, sizeof(ktime_t)); 2161 2162 wil_w(wil, ring->hwtail, ring->swhead); 2163 2164 return 0; 2165 dma_error: 2166 /* unmap what we have mapped */ 2167 nr_frags = f + 1; /* frags mapped + one for skb head */ 2168 for (f = 0; f < nr_frags; f++) { 2169 struct wil_ctx *ctx; 2170 2171 i = (swhead + f) % ring->size; 2172 ctx = &ring->ctx[i]; 2173 _d = &ring->va[i].tx.legacy; 2174 *d = *_d; 2175 _d->dma.status = TX_DMA_STATUS_DU; 2176 wil->txrx_ops.tx_desc_unmap(dev, 2177 (union wil_tx_desc *)d, 2178 ctx); 2179 2180 memset(ctx, 0, sizeof(*ctx)); 2181 } 2182 2183 return -EINVAL; 2184 } 2185 2186 static int wil_tx_ring(struct wil6210_priv *wil, struct wil6210_vif *vif, 2187 struct wil_ring *ring, struct sk_buff *skb) 2188 { 2189 int ring_index = ring - wil->ring_tx; 2190 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[ring_index]; 2191 int rc; 2192 2193 spin_lock(&txdata->lock); 2194 2195 if (test_bit(wil_status_suspending, wil->status) || 2196 test_bit(wil_status_suspended, wil->status) || 2197 test_bit(wil_status_resuming, wil->status)) { 2198 wil_dbg_txrx(wil, 2199 "suspend/resume in progress. drop packet\n"); 2200 spin_unlock(&txdata->lock); 2201 return -EINVAL; 2202 } 2203 2204 rc = (skb_is_gso(skb) ? wil->txrx_ops.tx_ring_tso : __wil_tx_ring) 2205 (wil, vif, ring, skb); 2206 2207 spin_unlock(&txdata->lock); 2208 2209 return rc; 2210 } 2211 2212 /* Check status of tx vrings and stop/wake net queues if needed 2213 * It will start/stop net queues of a specific VIF net_device. 2214 * 2215 * This function does one of two checks: 2216 * In case check_stop is true, will check if net queues need to be stopped. If 2217 * the conditions for stopping are met, netif_tx_stop_all_queues() is called. 2218 * In case check_stop is false, will check if net queues need to be waked. If 2219 * the conditions for waking are met, netif_tx_wake_all_queues() is called. 2220 * vring is the vring which is currently being modified by either adding 2221 * descriptors (tx) into it or removing descriptors (tx complete) from it. Can 2222 * be null when irrelevant (e.g. connect/disconnect events). 2223 * 2224 * The implementation is to stop net queues if modified vring has low 2225 * descriptor availability. Wake if all vrings are not in low descriptor 2226 * availability and modified vring has high descriptor availability. 2227 */ 2228 static inline void __wil_update_net_queues(struct wil6210_priv *wil, 2229 struct wil6210_vif *vif, 2230 struct wil_ring *ring, 2231 bool check_stop) 2232 { 2233 int i; 2234 int min_ring_id = wil_get_min_tx_ring_id(wil); 2235 2236 if (unlikely(!vif)) 2237 return; 2238 2239 if (ring) 2240 wil_dbg_txrx(wil, "vring %d, mid %d, check_stop=%d, stopped=%d", 2241 (int)(ring - wil->ring_tx), vif->mid, check_stop, 2242 vif->net_queue_stopped); 2243 else 2244 wil_dbg_txrx(wil, "check_stop=%d, mid=%d, stopped=%d", 2245 check_stop, vif->mid, vif->net_queue_stopped); 2246 2247 if (ring && drop_if_ring_full) 2248 /* no need to stop/wake net queues */ 2249 return; 2250 2251 if (check_stop == vif->net_queue_stopped) 2252 /* net queues already in desired state */ 2253 return; 2254 2255 if (check_stop) { 2256 if (!ring || unlikely(wil_ring_avail_low(ring))) { 2257 /* not enough room in the vring */ 2258 netif_tx_stop_all_queues(vif_to_ndev(vif)); 2259 vif->net_queue_stopped = true; 2260 wil_dbg_txrx(wil, "netif_tx_stop called\n"); 2261 } 2262 return; 2263 } 2264 2265 /* Do not wake the queues in suspend flow */ 2266 if (test_bit(wil_status_suspending, wil->status) || 2267 test_bit(wil_status_suspended, wil->status)) 2268 return; 2269 2270 /* check wake */ 2271 for (i = min_ring_id; i < WIL6210_MAX_TX_RINGS; i++) { 2272 struct wil_ring *cur_ring = &wil->ring_tx[i]; 2273 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[i]; 2274 2275 if (txdata->mid != vif->mid || !cur_ring->va || 2276 !txdata->enabled || cur_ring == ring) 2277 continue; 2278 2279 if (wil_ring_avail_low(cur_ring)) { 2280 wil_dbg_txrx(wil, "ring %d full, can't wake\n", 2281 (int)(cur_ring - wil->ring_tx)); 2282 return; 2283 } 2284 } 2285 2286 if (!ring || wil_ring_avail_high(ring)) { 2287 /* enough room in the ring */ 2288 wil_dbg_txrx(wil, "calling netif_tx_wake\n"); 2289 netif_tx_wake_all_queues(vif_to_ndev(vif)); 2290 vif->net_queue_stopped = false; 2291 } 2292 } 2293 2294 void wil_update_net_queues(struct wil6210_priv *wil, struct wil6210_vif *vif, 2295 struct wil_ring *ring, bool check_stop) 2296 { 2297 spin_lock(&wil->net_queue_lock); 2298 __wil_update_net_queues(wil, vif, ring, check_stop); 2299 spin_unlock(&wil->net_queue_lock); 2300 } 2301 2302 void wil_update_net_queues_bh(struct wil6210_priv *wil, struct wil6210_vif *vif, 2303 struct wil_ring *ring, bool check_stop) 2304 { 2305 spin_lock_bh(&wil->net_queue_lock); 2306 __wil_update_net_queues(wil, vif, ring, check_stop); 2307 spin_unlock_bh(&wil->net_queue_lock); 2308 } 2309 2310 netdev_tx_t wil_start_xmit(struct sk_buff *skb, struct net_device *ndev) 2311 { 2312 struct wil6210_vif *vif = ndev_to_vif(ndev); 2313 struct wil6210_priv *wil = vif_to_wil(vif); 2314 const u8 *da = wil_skb_get_da(skb); 2315 bool bcast = is_multicast_ether_addr(da); 2316 struct wil_ring *ring; 2317 static bool pr_once_fw; 2318 int rc; 2319 2320 wil_dbg_txrx(wil, "start_xmit\n"); 2321 if (unlikely(!test_bit(wil_status_fwready, wil->status))) { 2322 if (!pr_once_fw) { 2323 wil_err(wil, "FW not ready\n"); 2324 pr_once_fw = true; 2325 } 2326 goto drop; 2327 } 2328 if (unlikely(!test_bit(wil_vif_fwconnected, vif->status))) { 2329 wil_dbg_ratelimited(wil, 2330 "VIF not connected, packet dropped\n"); 2331 goto drop; 2332 } 2333 if (unlikely(vif->wdev.iftype == NL80211_IFTYPE_MONITOR)) { 2334 wil_err(wil, "Xmit in monitor mode not supported\n"); 2335 goto drop; 2336 } 2337 pr_once_fw = false; 2338 2339 /* find vring */ 2340 if (vif->wdev.iftype == NL80211_IFTYPE_STATION && !vif->pbss) { 2341 /* in STA mode (ESS), all to same VRING (to AP) */ 2342 ring = wil_find_tx_ring_sta(wil, vif, skb); 2343 } else if (bcast) { 2344 if (vif->pbss || wil_check_multicast_to_unicast(wil, skb)) 2345 /* in pbss, no bcast VRING - duplicate skb in 2346 * all stations VRINGs 2347 */ 2348 ring = wil_find_tx_bcast_2(wil, vif, skb); 2349 else if (vif->wdev.iftype == NL80211_IFTYPE_AP) 2350 /* AP has a dedicated bcast VRING */ 2351 ring = wil_find_tx_bcast_1(wil, vif, skb); 2352 else 2353 /* unexpected combination, fallback to duplicating 2354 * the skb in all stations VRINGs 2355 */ 2356 ring = wil_find_tx_bcast_2(wil, vif, skb); 2357 } else { 2358 /* unicast, find specific VRING by dest. address */ 2359 ring = wil_find_tx_ucast(wil, vif, skb); 2360 } 2361 if (unlikely(!ring)) { 2362 wil_dbg_txrx(wil, "No Tx RING found for %pM\n", da); 2363 goto drop; 2364 } 2365 /* set up vring entry */ 2366 rc = wil_tx_ring(wil, vif, ring, skb); 2367 2368 switch (rc) { 2369 case 0: 2370 /* shall we stop net queues? */ 2371 wil_update_net_queues_bh(wil, vif, ring, true); 2372 /* statistics will be updated on the tx_complete */ 2373 dev_kfree_skb_any(skb); 2374 return NETDEV_TX_OK; 2375 case -ENOMEM: 2376 if (drop_if_ring_full) 2377 goto drop; 2378 return NETDEV_TX_BUSY; 2379 default: 2380 break; /* goto drop; */ 2381 } 2382 drop: 2383 ndev->stats.tx_dropped++; 2384 dev_kfree_skb_any(skb); 2385 2386 return NET_XMIT_DROP; 2387 } 2388 2389 void wil_tx_latency_calc(struct wil6210_priv *wil, struct sk_buff *skb, 2390 struct wil_sta_info *sta) 2391 { 2392 int skb_time_us; 2393 int bin; 2394 2395 if (!wil->tx_latency) 2396 return; 2397 2398 if (ktime_to_ms(*(ktime_t *)&skb->cb) == 0) 2399 return; 2400 2401 skb_time_us = ktime_us_delta(ktime_get(), *(ktime_t *)&skb->cb); 2402 bin = skb_time_us / wil->tx_latency_res; 2403 bin = min_t(int, bin, WIL_NUM_LATENCY_BINS - 1); 2404 2405 wil_dbg_txrx(wil, "skb time %dus => bin %d\n", skb_time_us, bin); 2406 sta->tx_latency_bins[bin]++; 2407 sta->stats.tx_latency_total_us += skb_time_us; 2408 if (skb_time_us < sta->stats.tx_latency_min_us) 2409 sta->stats.tx_latency_min_us = skb_time_us; 2410 if (skb_time_us > sta->stats.tx_latency_max_us) 2411 sta->stats.tx_latency_max_us = skb_time_us; 2412 } 2413 2414 /* Clean up transmitted skb's from the Tx VRING 2415 * 2416 * Return number of descriptors cleared 2417 * 2418 * Safe to call from IRQ 2419 */ 2420 int wil_tx_complete(struct wil6210_vif *vif, int ringid) 2421 { 2422 struct wil6210_priv *wil = vif_to_wil(vif); 2423 struct net_device *ndev = vif_to_ndev(vif); 2424 struct device *dev = wil_to_dev(wil); 2425 struct wil_ring *vring = &wil->ring_tx[ringid]; 2426 struct wil_ring_tx_data *txdata = &wil->ring_tx_data[ringid]; 2427 int done = 0; 2428 int cid = wil->ring2cid_tid[ringid][0]; 2429 struct wil_net_stats *stats = NULL; 2430 volatile struct vring_tx_desc *_d; 2431 int used_before_complete; 2432 int used_new; 2433 2434 if (unlikely(!vring->va)) { 2435 wil_err(wil, "Tx irq[%d]: vring not initialized\n", ringid); 2436 return 0; 2437 } 2438 2439 if (unlikely(!txdata->enabled)) { 2440 wil_info(wil, "Tx irq[%d]: vring disabled\n", ringid); 2441 return 0; 2442 } 2443 2444 wil_dbg_txrx(wil, "tx_complete: (%d)\n", ringid); 2445 2446 used_before_complete = wil_ring_used_tx(vring); 2447 2448 if (cid < wil->max_assoc_sta) 2449 stats = &wil->sta[cid].stats; 2450 2451 while (!wil_ring_is_empty(vring)) { 2452 int new_swtail; 2453 struct wil_ctx *ctx = &vring->ctx[vring->swtail]; 2454 /* For the fragmented skb, HW will set DU bit only for the 2455 * last fragment. look for it. 2456 * In TSO the first DU will include hdr desc 2457 */ 2458 int lf = (vring->swtail + ctx->nr_frags) % vring->size; 2459 /* TODO: check we are not past head */ 2460 2461 _d = &vring->va[lf].tx.legacy; 2462 if (unlikely(!(_d->dma.status & TX_DMA_STATUS_DU))) 2463 break; 2464 2465 new_swtail = (lf + 1) % vring->size; 2466 while (vring->swtail != new_swtail) { 2467 struct vring_tx_desc dd, *d = ⅆ 2468 u16 dmalen; 2469 struct sk_buff *skb; 2470 2471 ctx = &vring->ctx[vring->swtail]; 2472 skb = ctx->skb; 2473 _d = &vring->va[vring->swtail].tx.legacy; 2474 2475 *d = *_d; 2476 2477 dmalen = le16_to_cpu(d->dma.length); 2478 trace_wil6210_tx_done(ringid, vring->swtail, dmalen, 2479 d->dma.error); 2480 wil_dbg_txrx(wil, 2481 "TxC[%2d][%3d] : %d bytes, status 0x%02x err 0x%02x\n", 2482 ringid, vring->swtail, dmalen, 2483 d->dma.status, d->dma.error); 2484 wil_hex_dump_txrx("TxCD ", DUMP_PREFIX_NONE, 32, 4, 2485 (const void *)d, sizeof(*d), false); 2486 2487 wil->txrx_ops.tx_desc_unmap(dev, 2488 (union wil_tx_desc *)d, 2489 ctx); 2490 2491 if (skb) { 2492 if (likely(d->dma.error == 0)) { 2493 ndev->stats.tx_packets++; 2494 ndev->stats.tx_bytes += skb->len; 2495 if (stats) { 2496 stats->tx_packets++; 2497 stats->tx_bytes += skb->len; 2498 2499 wil_tx_latency_calc(wil, skb, 2500 &wil->sta[cid]); 2501 } 2502 } else { 2503 ndev->stats.tx_errors++; 2504 if (stats) 2505 stats->tx_errors++; 2506 } 2507 2508 if (skb->protocol == cpu_to_be16(ETH_P_PAE)) 2509 wil_tx_complete_handle_eapol(vif, skb); 2510 2511 wil_consume_skb(skb, d->dma.error == 0); 2512 } 2513 memset(ctx, 0, sizeof(*ctx)); 2514 /* Make sure the ctx is zeroed before updating the tail 2515 * to prevent a case where wil_tx_ring will see 2516 * this descriptor as used and handle it before ctx zero 2517 * is completed. 2518 */ 2519 wmb(); 2520 /* There is no need to touch HW descriptor: 2521 * - ststus bit TX_DMA_STATUS_DU is set by design, 2522 * so hardware will not try to process this desc., 2523 * - rest of descriptor will be initialized on Tx. 2524 */ 2525 vring->swtail = wil_ring_next_tail(vring); 2526 done++; 2527 } 2528 } 2529 2530 /* performance monitoring */ 2531 used_new = wil_ring_used_tx(vring); 2532 if (wil_val_in_range(wil->ring_idle_trsh, 2533 used_new, used_before_complete)) { 2534 wil_dbg_txrx(wil, "Ring[%2d] idle %d -> %d\n", 2535 ringid, used_before_complete, used_new); 2536 txdata->last_idle = get_cycles(); 2537 } 2538 2539 /* shall we wake net queues? */ 2540 if (done) 2541 wil_update_net_queues(wil, vif, vring, false); 2542 2543 return done; 2544 } 2545 2546 static inline int wil_tx_init(struct wil6210_priv *wil) 2547 { 2548 return 0; 2549 } 2550 2551 static inline void wil_tx_fini(struct wil6210_priv *wil) {} 2552 2553 static void wil_get_reorder_params(struct wil6210_priv *wil, 2554 struct sk_buff *skb, int *tid, int *cid, 2555 int *mid, u16 *seq, int *mcast, int *retry) 2556 { 2557 struct vring_rx_desc *d = wil_skb_rxdesc(skb); 2558 2559 *tid = wil_rxdesc_tid(d); 2560 *cid = wil_skb_get_cid(skb); 2561 *mid = wil_rxdesc_mid(d); 2562 *seq = wil_rxdesc_seq(d); 2563 *mcast = wil_rxdesc_mcast(d); 2564 *retry = wil_rxdesc_retry(d); 2565 } 2566 2567 void wil_init_txrx_ops_legacy_dma(struct wil6210_priv *wil) 2568 { 2569 wil->txrx_ops.configure_interrupt_moderation = 2570 wil_configure_interrupt_moderation; 2571 /* TX ops */ 2572 wil->txrx_ops.tx_desc_map = wil_tx_desc_map; 2573 wil->txrx_ops.tx_desc_unmap = wil_txdesc_unmap; 2574 wil->txrx_ops.tx_ring_tso = __wil_tx_vring_tso; 2575 wil->txrx_ops.ring_init_tx = wil_vring_init_tx; 2576 wil->txrx_ops.ring_fini_tx = wil_vring_free; 2577 wil->txrx_ops.ring_init_bcast = wil_vring_init_bcast; 2578 wil->txrx_ops.tx_init = wil_tx_init; 2579 wil->txrx_ops.tx_fini = wil_tx_fini; 2580 wil->txrx_ops.tx_ring_modify = wil_tx_vring_modify; 2581 /* RX ops */ 2582 wil->txrx_ops.rx_init = wil_rx_init; 2583 wil->txrx_ops.wmi_addba_rx_resp = wmi_addba_rx_resp; 2584 wil->txrx_ops.get_reorder_params = wil_get_reorder_params; 2585 wil->txrx_ops.get_netif_rx_params = 2586 wil_get_netif_rx_params; 2587 wil->txrx_ops.rx_crypto_check = wil_rx_crypto_check; 2588 wil->txrx_ops.rx_error_check = wil_rx_error_check; 2589 wil->txrx_ops.is_rx_idle = wil_is_rx_idle; 2590 wil->txrx_ops.rx_fini = wil_rx_fini; 2591 } 2592