1 /* 2 * Copyright (c) 2014-2019 The Linux Foundation. All rights reserved. 3 * 4 * Permission to use, copy, modify, and/or distribute this software for 5 * any purpose with or without fee is hereby granted, provided that the 6 * above copyright notice and this permission notice appear in all 7 * copies. 8 * 9 * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL 10 * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED 11 * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE 12 * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL 13 * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR 14 * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER 15 * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR 16 * PERFORMANCE OF THIS SOFTWARE. 17 */ 18 19 /** 20 * DOC: qdf_nbuf.c 21 * QCA driver framework(QDF) network buffer management APIs 22 */ 23 24 #include <linux/hashtable.h> 25 #include <linux/kernel.h> 26 #include <linux/version.h> 27 #include <linux/skbuff.h> 28 #include <linux/module.h> 29 #include <linux/proc_fs.h> 30 #include <qdf_atomic.h> 31 #include <qdf_types.h> 32 #include <qdf_nbuf.h> 33 #include "qdf_flex_mem.h" 34 #include <qdf_mem.h> 35 #include <qdf_status.h> 36 #include <qdf_lock.h> 37 #include <qdf_trace.h> 38 #include <qdf_debugfs.h> 39 #include <net/ieee80211_radiotap.h> 40 #include <qdf_module.h> 41 #include <qdf_atomic.h> 42 #include <pld_common.h> 43 #include <qdf_module.h> 44 #include "qdf_str.h" 45 46 #if defined(FEATURE_TSO) 47 #include <net/ipv6.h> 48 #include <linux/ipv6.h> 49 #include <linux/tcp.h> 50 #include <linux/if_vlan.h> 51 #include <linux/ip.h> 52 #endif /* FEATURE_TSO */ 53 54 #if LINUX_VERSION_CODE < KERNEL_VERSION(4, 13, 0) 55 56 #define qdf_nbuf_users_inc atomic_inc 57 #define qdf_nbuf_users_dec atomic_dec 58 #define qdf_nbuf_users_set atomic_set 59 #define qdf_nbuf_users_read atomic_read 60 #else 61 #define qdf_nbuf_users_inc refcount_inc 62 #define qdf_nbuf_users_dec refcount_dec 63 #define qdf_nbuf_users_set refcount_set 64 #define qdf_nbuf_users_read refcount_read 65 #endif /* KERNEL_VERSION(4, 13, 0) */ 66 67 #define IEEE80211_RADIOTAP_VHT_BW_20 0 68 #define IEEE80211_RADIOTAP_VHT_BW_40 1 69 #define IEEE80211_RADIOTAP_VHT_BW_80 2 70 #define IEEE80211_RADIOTAP_VHT_BW_160 3 71 72 #define RADIOTAP_VHT_BW_20 0 73 #define RADIOTAP_VHT_BW_40 1 74 #define RADIOTAP_VHT_BW_80 4 75 #define RADIOTAP_VHT_BW_160 11 76 77 /* channel number to freq conversion */ 78 #define CHANNEL_NUM_14 14 79 #define CHANNEL_NUM_15 15 80 #define CHANNEL_NUM_27 27 81 #define CHANNEL_NUM_35 35 82 #define CHANNEL_NUM_182 182 83 #define CHANNEL_NUM_197 197 84 #define CHANNEL_FREQ_2484 2484 85 #define CHANNEL_FREQ_2407 2407 86 #define CHANNEL_FREQ_2512 2512 87 #define CHANNEL_FREQ_5000 5000 88 #define CHANNEL_FREQ_4000 4000 89 #define FREQ_MULTIPLIER_CONST_5MHZ 5 90 #define FREQ_MULTIPLIER_CONST_20MHZ 20 91 #define RADIOTAP_5G_SPECTRUM_CHANNEL 0x0100 92 #define RADIOTAP_2G_SPECTRUM_CHANNEL 0x0080 93 #define RADIOTAP_CCK_CHANNEL 0x0020 94 #define RADIOTAP_OFDM_CHANNEL 0x0040 95 96 #ifdef CONFIG_MCL 97 #include <qdf_mc_timer.h> 98 99 struct qdf_track_timer { 100 qdf_mc_timer_t track_timer; 101 qdf_atomic_t alloc_fail_cnt; 102 }; 103 104 static struct qdf_track_timer alloc_track_timer; 105 106 #define QDF_NBUF_ALLOC_EXPIRE_TIMER_MS 5000 107 #define QDF_NBUF_ALLOC_EXPIRE_CNT_THRESHOLD 50 108 #endif 109 110 /* Packet Counter */ 111 static uint32_t nbuf_tx_mgmt[QDF_NBUF_TX_PKT_STATE_MAX]; 112 static uint32_t nbuf_tx_data[QDF_NBUF_TX_PKT_STATE_MAX]; 113 #ifdef QDF_NBUF_GLOBAL_COUNT 114 #define NBUF_DEBUGFS_NAME "nbuf_counters" 115 static qdf_atomic_t nbuf_count; 116 #endif 117 118 /** 119 * qdf_nbuf_tx_desc_count_display() - Displays the packet counter 120 * 121 * Return: none 122 */ 123 void qdf_nbuf_tx_desc_count_display(void) 124 { 125 qdf_debug("Current Snapshot of the Driver:"); 126 qdf_debug("Data Packets:"); 127 qdf_debug("HDD %d TXRX_Q %d TXRX %d HTT %d", 128 nbuf_tx_data[QDF_NBUF_TX_PKT_HDD] - 129 (nbuf_tx_data[QDF_NBUF_TX_PKT_TXRX] + 130 nbuf_tx_data[QDF_NBUF_TX_PKT_TXRX_ENQUEUE] - 131 nbuf_tx_data[QDF_NBUF_TX_PKT_TXRX_DEQUEUE]), 132 nbuf_tx_data[QDF_NBUF_TX_PKT_TXRX_ENQUEUE] - 133 nbuf_tx_data[QDF_NBUF_TX_PKT_TXRX_DEQUEUE], 134 nbuf_tx_data[QDF_NBUF_TX_PKT_TXRX] - 135 nbuf_tx_data[QDF_NBUF_TX_PKT_HTT], 136 nbuf_tx_data[QDF_NBUF_TX_PKT_HTT] - 137 nbuf_tx_data[QDF_NBUF_TX_PKT_HTC]); 138 qdf_debug(" HTC %d HIF %d CE %d TX_COMP %d", 139 nbuf_tx_data[QDF_NBUF_TX_PKT_HTC] - 140 nbuf_tx_data[QDF_NBUF_TX_PKT_HIF], 141 nbuf_tx_data[QDF_NBUF_TX_PKT_HIF] - 142 nbuf_tx_data[QDF_NBUF_TX_PKT_CE], 143 nbuf_tx_data[QDF_NBUF_TX_PKT_CE] - 144 nbuf_tx_data[QDF_NBUF_TX_PKT_FREE], 145 nbuf_tx_data[QDF_NBUF_TX_PKT_FREE]); 146 qdf_debug("Mgmt Packets:"); 147 qdf_debug("TXRX_Q %d TXRX %d HTT %d HTC %d HIF %d CE %d TX_COMP %d", 148 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_TXRX_ENQUEUE] - 149 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_TXRX_DEQUEUE], 150 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_TXRX] - 151 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_HTT], 152 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_HTT] - 153 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_HTC], 154 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_HTC] - 155 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_HIF], 156 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_HIF] - 157 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_CE], 158 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_CE] - 159 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_FREE], 160 nbuf_tx_mgmt[QDF_NBUF_TX_PKT_FREE]); 161 } 162 qdf_export_symbol(qdf_nbuf_tx_desc_count_display); 163 164 /** 165 * qdf_nbuf_tx_desc_count_update() - Updates the layer packet counter 166 * @packet_type : packet type either mgmt/data 167 * @current_state : layer at which the packet currently present 168 * 169 * Return: none 170 */ 171 static inline void qdf_nbuf_tx_desc_count_update(uint8_t packet_type, 172 uint8_t current_state) 173 { 174 switch (packet_type) { 175 case QDF_NBUF_TX_PKT_MGMT_TRACK: 176 nbuf_tx_mgmt[current_state]++; 177 break; 178 case QDF_NBUF_TX_PKT_DATA_TRACK: 179 nbuf_tx_data[current_state]++; 180 break; 181 default: 182 break; 183 } 184 } 185 qdf_export_symbol(qdf_nbuf_tx_desc_count_update); 186 187 /** 188 * qdf_nbuf_tx_desc_count_clear() - Clears packet counter for both data, mgmt 189 * 190 * Return: none 191 */ 192 void qdf_nbuf_tx_desc_count_clear(void) 193 { 194 memset(nbuf_tx_mgmt, 0, sizeof(nbuf_tx_mgmt)); 195 memset(nbuf_tx_data, 0, sizeof(nbuf_tx_data)); 196 } 197 qdf_export_symbol(qdf_nbuf_tx_desc_count_clear); 198 199 /** 200 * qdf_nbuf_set_state() - Updates the packet state 201 * @nbuf: network buffer 202 * @current_state : layer at which the packet currently is 203 * 204 * This function updates the packet state to the layer at which the packet 205 * currently is 206 * 207 * Return: none 208 */ 209 void qdf_nbuf_set_state(qdf_nbuf_t nbuf, uint8_t current_state) 210 { 211 /* 212 * Only Mgmt, Data Packets are tracked. WMI messages 213 * such as scan commands are not tracked 214 */ 215 uint8_t packet_type; 216 217 packet_type = QDF_NBUF_CB_TX_PACKET_TRACK(nbuf); 218 219 if ((packet_type != QDF_NBUF_TX_PKT_DATA_TRACK) && 220 (packet_type != QDF_NBUF_TX_PKT_MGMT_TRACK)) { 221 return; 222 } 223 QDF_NBUF_CB_TX_PACKET_STATE(nbuf) = current_state; 224 qdf_nbuf_tx_desc_count_update(packet_type, 225 current_state); 226 } 227 qdf_export_symbol(qdf_nbuf_set_state); 228 229 #ifdef CONFIG_MCL 230 /** 231 * __qdf_nbuf_start_replenish_timer - Start alloc fail replenish timer 232 * 233 * This function starts the alloc fail replenish timer. 234 * 235 * Return: void 236 */ 237 static void __qdf_nbuf_start_replenish_timer(void) 238 { 239 qdf_atomic_inc(&alloc_track_timer.alloc_fail_cnt); 240 if (qdf_mc_timer_get_current_state(&alloc_track_timer.track_timer) != 241 QDF_TIMER_STATE_RUNNING) 242 qdf_mc_timer_start(&alloc_track_timer.track_timer, 243 QDF_NBUF_ALLOC_EXPIRE_TIMER_MS); 244 } 245 246 /** 247 * __qdf_nbuf_stop_replenish_timer - Stop alloc fail replenish timer 248 * 249 * This function stops the alloc fail replenish timer. 250 * 251 * Return: void 252 */ 253 static void __qdf_nbuf_stop_replenish_timer(void) 254 { 255 if (qdf_atomic_read(&alloc_track_timer.alloc_fail_cnt) == 0) 256 return; 257 258 qdf_atomic_set(&alloc_track_timer.alloc_fail_cnt, 0); 259 if (qdf_mc_timer_get_current_state(&alloc_track_timer.track_timer) == 260 QDF_TIMER_STATE_RUNNING) 261 qdf_mc_timer_stop(&alloc_track_timer.track_timer); 262 } 263 264 /** 265 * qdf_replenish_expire_handler - Replenish expire handler 266 * 267 * This function triggers when the alloc fail replenish timer expires. 268 * 269 * Return: void 270 */ 271 static void qdf_replenish_expire_handler(void *arg) 272 { 273 if (qdf_atomic_read(&alloc_track_timer.alloc_fail_cnt) > 274 QDF_NBUF_ALLOC_EXPIRE_CNT_THRESHOLD) { 275 qdf_print("ERROR: NBUF allocation timer expired Fail count %d", 276 qdf_atomic_read(&alloc_track_timer.alloc_fail_cnt)); 277 278 /* Error handling here */ 279 } 280 } 281 282 /** 283 * __qdf_nbuf_init_replenish_timer - Initialize the alloc replenish timer 284 * 285 * This function initializes the nbuf alloc fail replenish timer. 286 * 287 * Return: void 288 */ 289 void __qdf_nbuf_init_replenish_timer(void) 290 { 291 qdf_mc_timer_init(&alloc_track_timer.track_timer, QDF_TIMER_TYPE_SW, 292 qdf_replenish_expire_handler, NULL); 293 } 294 295 /** 296 * __qdf_nbuf_deinit_replenish_timer - Deinitialize the alloc replenish timer 297 * 298 * This function deinitializes the nbuf alloc fail replenish timer. 299 * 300 * Return: void 301 */ 302 void __qdf_nbuf_deinit_replenish_timer(void) 303 { 304 __qdf_nbuf_stop_replenish_timer(); 305 qdf_mc_timer_destroy(&alloc_track_timer.track_timer); 306 } 307 #else 308 309 static inline void __qdf_nbuf_start_replenish_timer(void) {} 310 static inline void __qdf_nbuf_stop_replenish_timer(void) {} 311 #endif 312 313 /* globals do not need to be initialized to NULL/0 */ 314 qdf_nbuf_trace_update_t qdf_trace_update_cb; 315 qdf_nbuf_free_t nbuf_free_cb; 316 317 #ifdef QDF_NBUF_GLOBAL_COUNT 318 319 /** 320 * __qdf_nbuf_count_get() - get nbuf global count 321 * 322 * Return: nbuf global count 323 */ 324 int __qdf_nbuf_count_get(void) 325 { 326 return qdf_atomic_read(&nbuf_count); 327 } 328 qdf_export_symbol(__qdf_nbuf_count_get); 329 330 /** 331 * __qdf_nbuf_count_inc() - increment nbuf global count 332 * 333 * @buf: sk buff 334 * 335 * Return: void 336 */ 337 void __qdf_nbuf_count_inc(qdf_nbuf_t nbuf) 338 { 339 qdf_atomic_inc(&nbuf_count); 340 } 341 qdf_export_symbol(__qdf_nbuf_count_inc); 342 343 /** 344 * __qdf_nbuf_count_dec() - decrement nbuf global count 345 * 346 * @buf: sk buff 347 * 348 * Return: void 349 */ 350 void __qdf_nbuf_count_dec(__qdf_nbuf_t nbuf) 351 { 352 qdf_atomic_dec(&nbuf_count); 353 } 354 qdf_export_symbol(__qdf_nbuf_count_dec); 355 #endif 356 357 #if defined(QCA_WIFI_QCA8074) && defined (BUILD_X86) 358 struct sk_buff *__qdf_nbuf_alloc(qdf_device_t osdev, size_t size, int reserve, 359 int align, int prio, const char *func, 360 uint32_t line) 361 { 362 struct sk_buff *skb; 363 unsigned long offset; 364 uint32_t lowmem_alloc_tries = 0; 365 366 if (align) 367 size += (align - 1); 368 369 realloc: 370 skb = dev_alloc_skb(size); 371 372 if (skb) 373 goto skb_alloc; 374 375 skb = pld_nbuf_pre_alloc(size); 376 377 if (!skb) { 378 qdf_rl_nofl_err("NBUF alloc failed %zuB @ %s:%d", 379 size, func, line); 380 return NULL; 381 } 382 383 skb_alloc: 384 /* Hawkeye M2M emulation cannot handle memory addresses below 0x50000040 385 * Though we are trying to reserve low memory upfront to prevent this, 386 * we sometimes see SKBs allocated from low memory. 387 */ 388 if (virt_to_phys(qdf_nbuf_data(skb)) < 0x50000040) { 389 lowmem_alloc_tries++; 390 if (lowmem_alloc_tries > 100) { 391 qdf_nofl_err("NBUF alloc failed %zuB @ %s:%d", 392 size, func, line); 393 return NULL; 394 } else { 395 /* Not freeing to make sure it 396 * will not get allocated again 397 */ 398 goto realloc; 399 } 400 } 401 memset(skb->cb, 0x0, sizeof(skb->cb)); 402 403 /* 404 * The default is for netbuf fragments to be interpreted 405 * as wordstreams rather than bytestreams. 406 */ 407 QDF_NBUF_CB_TX_EXTRA_FRAG_WORDSTR_EFRAG(skb) = 1; 408 QDF_NBUF_CB_TX_EXTRA_FRAG_WORDSTR_NBUF(skb) = 1; 409 410 /* 411 * XXX:how about we reserve first then align 412 * Align & make sure that the tail & data are adjusted properly 413 */ 414 415 if (align) { 416 offset = ((unsigned long)skb->data) % align; 417 if (offset) 418 skb_reserve(skb, align - offset); 419 } 420 421 /* 422 * NOTE:alloc doesn't take responsibility if reserve unaligns the data 423 * pointer 424 */ 425 skb_reserve(skb, reserve); 426 qdf_nbuf_count_inc(skb); 427 428 return skb; 429 } 430 #else 431 struct sk_buff *__qdf_nbuf_alloc(qdf_device_t osdev, size_t size, int reserve, 432 int align, int prio, const char *func, 433 uint32_t line) 434 { 435 struct sk_buff *skb; 436 unsigned long offset; 437 int flags = GFP_KERNEL; 438 439 if (align) 440 size += (align - 1); 441 442 if (in_interrupt() || irqs_disabled() || in_atomic()) { 443 flags = GFP_ATOMIC; 444 #if LINUX_VERSION_CODE >= KERNEL_VERSION(4, 4, 0) 445 /* 446 * Observed that kcompactd burns out CPU to make order-3 page. 447 *__netdev_alloc_skb has 4k page fallback option just in case of 448 * failing high order page allocation so we don't need to be 449 * hard. Make kcompactd rest in piece. 450 */ 451 flags = flags & ~__GFP_KSWAPD_RECLAIM; 452 #endif 453 } 454 455 skb = __netdev_alloc_skb(NULL, size, flags); 456 457 if (skb) 458 goto skb_alloc; 459 460 skb = pld_nbuf_pre_alloc(size); 461 462 if (!skb) { 463 qdf_rl_nofl_err("NBUF alloc failed %zuB @ %s:%d", 464 size, func, line); 465 __qdf_nbuf_start_replenish_timer(); 466 return NULL; 467 } else { 468 __qdf_nbuf_stop_replenish_timer(); 469 } 470 471 skb_alloc: 472 memset(skb->cb, 0x0, sizeof(skb->cb)); 473 474 /* 475 * The default is for netbuf fragments to be interpreted 476 * as wordstreams rather than bytestreams. 477 */ 478 QDF_NBUF_CB_TX_EXTRA_FRAG_WORDSTR_EFRAG(skb) = 1; 479 QDF_NBUF_CB_TX_EXTRA_FRAG_WORDSTR_NBUF(skb) = 1; 480 481 /* 482 * XXX:how about we reserve first then align 483 * Align & make sure that the tail & data are adjusted properly 484 */ 485 486 if (align) { 487 offset = ((unsigned long)skb->data) % align; 488 if (offset) 489 skb_reserve(skb, align - offset); 490 } 491 492 /* 493 * NOTE:alloc doesn't take responsibility if reserve unaligns the data 494 * pointer 495 */ 496 skb_reserve(skb, reserve); 497 qdf_nbuf_count_inc(skb); 498 499 return skb; 500 } 501 #endif 502 qdf_export_symbol(__qdf_nbuf_alloc); 503 504 /** 505 * __qdf_nbuf_free() - free the nbuf its interrupt safe 506 * @skb: Pointer to network buffer 507 * 508 * Return: none 509 */ 510 511 #ifdef CONFIG_MCL 512 void __qdf_nbuf_free(struct sk_buff *skb) 513 { 514 if (pld_nbuf_pre_alloc_free(skb)) 515 return; 516 517 qdf_nbuf_count_dec(skb); 518 if (nbuf_free_cb) 519 nbuf_free_cb(skb); 520 else 521 dev_kfree_skb_any(skb); 522 } 523 #else 524 void __qdf_nbuf_free(struct sk_buff *skb) 525 { 526 if (pld_nbuf_pre_alloc_free(skb)) 527 return; 528 529 qdf_nbuf_count_dec(skb); 530 dev_kfree_skb_any(skb); 531 } 532 #endif 533 534 qdf_export_symbol(__qdf_nbuf_free); 535 536 #ifdef NBUF_MEMORY_DEBUG 537 enum qdf_nbuf_event_type { 538 QDF_NBUF_ALLOC, 539 QDF_NBUF_ALLOC_FAILURE, 540 QDF_NBUF_FREE, 541 QDF_NBUF_MAP, 542 QDF_NBUF_UNMAP, 543 }; 544 545 struct qdf_nbuf_event { 546 qdf_nbuf_t nbuf; 547 char func[QDF_MEM_FUNC_NAME_SIZE]; 548 uint32_t line; 549 enum qdf_nbuf_event_type type; 550 uint64_t timestamp; 551 }; 552 553 #define QDF_NBUF_HISTORY_SIZE 4096 554 static qdf_atomic_t qdf_nbuf_history_index; 555 static struct qdf_nbuf_event qdf_nbuf_history[QDF_NBUF_HISTORY_SIZE]; 556 557 static int32_t qdf_nbuf_circular_index_next(qdf_atomic_t *index, int size) 558 { 559 int32_t next = qdf_atomic_inc_return(index); 560 561 if (next == size) 562 qdf_atomic_sub(size, index); 563 564 return next % size; 565 } 566 567 static void 568 qdf_nbuf_history_add(qdf_nbuf_t nbuf, const char *func, uint32_t line, 569 enum qdf_nbuf_event_type type) 570 { 571 int32_t idx = qdf_nbuf_circular_index_next(&qdf_nbuf_history_index, 572 QDF_NBUF_HISTORY_SIZE); 573 struct qdf_nbuf_event *event = &qdf_nbuf_history[idx]; 574 575 event->nbuf = nbuf; 576 qdf_str_lcopy(event->func, func, QDF_MEM_FUNC_NAME_SIZE); 577 event->line = line; 578 event->type = type; 579 event->timestamp = qdf_get_log_timestamp(); 580 } 581 #endif /* NBUF_MEMORY_DEBUG */ 582 583 #ifdef NBUF_MAP_UNMAP_DEBUG 584 struct qdf_nbuf_map_metadata { 585 struct hlist_node node; 586 qdf_nbuf_t nbuf; 587 char func[QDF_MEM_FUNC_NAME_SIZE]; 588 uint32_t line; 589 }; 590 591 DEFINE_QDF_FLEX_MEM_POOL(qdf_nbuf_map_pool, 592 sizeof(struct qdf_nbuf_map_metadata), 0); 593 #define QDF_NBUF_MAP_HT_BITS 10 /* 1024 buckets */ 594 static DECLARE_HASHTABLE(qdf_nbuf_map_ht, QDF_NBUF_MAP_HT_BITS); 595 static qdf_spinlock_t qdf_nbuf_map_lock; 596 597 static void qdf_nbuf_map_tracking_init(void) 598 { 599 qdf_flex_mem_init(&qdf_nbuf_map_pool); 600 hash_init(qdf_nbuf_map_ht); 601 qdf_spinlock_create(&qdf_nbuf_map_lock); 602 } 603 604 static void qdf_nbuf_map_leaks_print(void) 605 { 606 struct qdf_nbuf_map_metadata *meta; 607 int bucket; 608 uint32_t count = 0; 609 610 QDF_BUG(qdf_spin_is_locked(&qdf_nbuf_map_lock)); 611 612 qdf_nofl_alert("Nbuf map-no-unmap events detected!"); 613 qdf_nofl_alert("-----------------------------------------------------"); 614 615 hash_for_each(qdf_nbuf_map_ht, bucket, meta, node) { 616 count++; 617 qdf_nofl_alert("0x%zx @ %s:%u", 618 (uintptr_t)meta->nbuf, meta->func, meta->line); 619 } 620 621 QDF_DEBUG_PANIC("%u fatal nbuf map-no-unmap events detected!", count); 622 } 623 624 void qdf_nbuf_map_check_for_leaks(void) 625 { 626 qdf_flex_mem_release(&qdf_nbuf_map_pool); 627 628 qdf_spin_lock_irqsave(&qdf_nbuf_map_lock); 629 if (!hash_empty(qdf_nbuf_map_ht)) 630 qdf_nbuf_map_leaks_print(); 631 qdf_spin_unlock_irqrestore(&qdf_nbuf_map_lock); 632 } 633 634 static void qdf_nbuf_map_tracking_deinit(void) 635 { 636 qdf_nbuf_map_check_for_leaks(); 637 qdf_spinlock_destroy(&qdf_nbuf_map_lock); 638 qdf_flex_mem_deinit(&qdf_nbuf_map_pool); 639 } 640 641 static struct qdf_nbuf_map_metadata *qdf_nbuf_meta_get(qdf_nbuf_t nbuf) 642 { 643 struct qdf_nbuf_map_metadata *meta; 644 645 hash_for_each_possible(qdf_nbuf_map_ht, meta, node, (size_t)nbuf) { 646 if (meta->nbuf == nbuf) 647 return meta; 648 } 649 650 return NULL; 651 } 652 653 static QDF_STATUS 654 qdf_nbuf_track_map(qdf_nbuf_t nbuf, const char *func, uint32_t line) 655 { 656 struct qdf_nbuf_map_metadata *meta; 657 658 QDF_BUG(nbuf); 659 if (!nbuf) { 660 qdf_err("Cannot map null nbuf"); 661 return QDF_STATUS_E_INVAL; 662 } 663 664 qdf_spin_lock_irqsave(&qdf_nbuf_map_lock); 665 meta = qdf_nbuf_meta_get(nbuf); 666 qdf_spin_unlock_irqrestore(&qdf_nbuf_map_lock); 667 if (meta) 668 QDF_DEBUG_PANIC( 669 "Double nbuf map detected @ %s:%u; last map from %s:%u", 670 func, line, meta->func, meta->line); 671 672 meta = qdf_flex_mem_alloc(&qdf_nbuf_map_pool); 673 if (!meta) { 674 qdf_err("Failed to allocate nbuf map tracking metadata"); 675 return QDF_STATUS_E_NOMEM; 676 } 677 678 meta->nbuf = nbuf; 679 qdf_str_lcopy(meta->func, func, QDF_MEM_FUNC_NAME_SIZE); 680 meta->line = line; 681 682 qdf_spin_lock_irqsave(&qdf_nbuf_map_lock); 683 hash_add(qdf_nbuf_map_ht, &meta->node, (size_t)nbuf); 684 qdf_spin_unlock_irqrestore(&qdf_nbuf_map_lock); 685 686 qdf_nbuf_history_add(nbuf, func, line, QDF_NBUF_MAP); 687 688 return QDF_STATUS_SUCCESS; 689 } 690 691 static void 692 qdf_nbuf_untrack_map(qdf_nbuf_t nbuf, const char *func, uint32_t line) 693 { 694 struct qdf_nbuf_map_metadata *meta; 695 696 QDF_BUG(nbuf); 697 if (!nbuf) { 698 qdf_err("Cannot unmap null nbuf"); 699 return; 700 } 701 702 qdf_spin_lock_irqsave(&qdf_nbuf_map_lock); 703 meta = qdf_nbuf_meta_get(nbuf); 704 705 if (!meta) 706 QDF_DEBUG_PANIC( 707 "Double nbuf unmap or unmap without map detected @ %s:%u", 708 func, line); 709 710 hash_del(&meta->node); 711 qdf_spin_unlock_irqrestore(&qdf_nbuf_map_lock); 712 713 qdf_flex_mem_free(&qdf_nbuf_map_pool, meta); 714 715 qdf_nbuf_history_add(nbuf, func, line, QDF_NBUF_UNMAP); 716 } 717 718 QDF_STATUS qdf_nbuf_map_debug(qdf_device_t osdev, 719 qdf_nbuf_t buf, 720 qdf_dma_dir_t dir, 721 const char *func, 722 uint32_t line) 723 { 724 QDF_STATUS status; 725 726 status = qdf_nbuf_track_map(buf, func, line); 727 if (QDF_IS_STATUS_ERROR(status)) 728 return status; 729 730 status = __qdf_nbuf_map(osdev, buf, dir); 731 if (QDF_IS_STATUS_ERROR(status)) 732 qdf_nbuf_untrack_map(buf, func, line); 733 734 return status; 735 } 736 737 qdf_export_symbol(qdf_nbuf_map_debug); 738 739 void qdf_nbuf_unmap_debug(qdf_device_t osdev, 740 qdf_nbuf_t buf, 741 qdf_dma_dir_t dir, 742 const char *func, 743 uint32_t line) 744 { 745 qdf_nbuf_untrack_map(buf, func, line); 746 __qdf_nbuf_unmap_single(osdev, buf, dir); 747 } 748 749 qdf_export_symbol(qdf_nbuf_unmap_debug); 750 751 QDF_STATUS qdf_nbuf_map_single_debug(qdf_device_t osdev, 752 qdf_nbuf_t buf, 753 qdf_dma_dir_t dir, 754 const char *func, 755 uint32_t line) 756 { 757 QDF_STATUS status; 758 759 status = qdf_nbuf_track_map(buf, func, line); 760 if (QDF_IS_STATUS_ERROR(status)) 761 return status; 762 763 status = __qdf_nbuf_map_single(osdev, buf, dir); 764 if (QDF_IS_STATUS_ERROR(status)) 765 qdf_nbuf_untrack_map(buf, func, line); 766 767 return status; 768 } 769 770 qdf_export_symbol(qdf_nbuf_map_single_debug); 771 772 void qdf_nbuf_unmap_single_debug(qdf_device_t osdev, 773 qdf_nbuf_t buf, 774 qdf_dma_dir_t dir, 775 const char *func, 776 uint32_t line) 777 { 778 qdf_nbuf_untrack_map(buf, func, line); 779 __qdf_nbuf_unmap_single(osdev, buf, dir); 780 } 781 782 qdf_export_symbol(qdf_nbuf_unmap_single_debug); 783 784 QDF_STATUS qdf_nbuf_map_nbytes_debug(qdf_device_t osdev, 785 qdf_nbuf_t buf, 786 qdf_dma_dir_t dir, 787 int nbytes, 788 const char *func, 789 uint32_t line) 790 { 791 QDF_STATUS status; 792 793 status = qdf_nbuf_track_map(buf, func, line); 794 if (QDF_IS_STATUS_ERROR(status)) 795 return status; 796 797 status = __qdf_nbuf_map_nbytes(osdev, buf, dir, nbytes); 798 if (QDF_IS_STATUS_ERROR(status)) 799 qdf_nbuf_untrack_map(buf, func, line); 800 801 return status; 802 } 803 804 qdf_export_symbol(qdf_nbuf_map_nbytes_debug); 805 806 void qdf_nbuf_unmap_nbytes_debug(qdf_device_t osdev, 807 qdf_nbuf_t buf, 808 qdf_dma_dir_t dir, 809 int nbytes, 810 const char *func, 811 uint32_t line) 812 { 813 qdf_nbuf_untrack_map(buf, func, line); 814 __qdf_nbuf_unmap_nbytes(osdev, buf, dir, nbytes); 815 } 816 817 qdf_export_symbol(qdf_nbuf_unmap_nbytes_debug); 818 819 QDF_STATUS qdf_nbuf_map_nbytes_single_debug(qdf_device_t osdev, 820 qdf_nbuf_t buf, 821 qdf_dma_dir_t dir, 822 int nbytes, 823 const char *func, 824 uint32_t line) 825 { 826 QDF_STATUS status; 827 828 status = qdf_nbuf_track_map(buf, func, line); 829 if (QDF_IS_STATUS_ERROR(status)) 830 return status; 831 832 status = __qdf_nbuf_map_nbytes_single(osdev, buf, dir, nbytes); 833 if (QDF_IS_STATUS_ERROR(status)) 834 qdf_nbuf_untrack_map(buf, func, line); 835 836 return status; 837 } 838 839 qdf_export_symbol(qdf_nbuf_map_nbytes_single_debug); 840 841 void qdf_nbuf_unmap_nbytes_single_debug(qdf_device_t osdev, 842 qdf_nbuf_t buf, 843 qdf_dma_dir_t dir, 844 int nbytes, 845 const char *func, 846 uint32_t line) 847 { 848 qdf_nbuf_untrack_map(buf, func, line); 849 __qdf_nbuf_unmap_nbytes_single(osdev, buf, dir, nbytes); 850 } 851 852 qdf_export_symbol(qdf_nbuf_unmap_nbytes_single_debug); 853 854 static void qdf_nbuf_panic_on_free_if_mapped(qdf_nbuf_t nbuf, const char *func, 855 uint32_t line) 856 { 857 struct qdf_nbuf_map_metadata *meta; 858 859 qdf_spin_lock_irqsave(&qdf_nbuf_map_lock); 860 meta = qdf_nbuf_meta_get(nbuf); 861 if (meta) 862 QDF_DEBUG_PANIC( 863 "Nbuf freed @ %s:%u while mapped from %s:%u", 864 kbasename(func), line, meta->func, meta->line); 865 qdf_spin_unlock_irqrestore(&qdf_nbuf_map_lock); 866 } 867 #else 868 static inline void qdf_nbuf_map_tracking_init(void) 869 { 870 } 871 872 static inline void qdf_nbuf_map_tracking_deinit(void) 873 { 874 } 875 876 static inline void qdf_nbuf_panic_on_free_if_mapped(qdf_nbuf_t nbuf, 877 const char *func, 878 uint32_t line) 879 { 880 } 881 #endif /* NBUF_MAP_UNMAP_DEBUG */ 882 883 /** 884 * __qdf_nbuf_map() - map a buffer to local bus address space 885 * @osdev: OS device 886 * @bmap: Bitmap 887 * @skb: Pointer to network buffer 888 * @dir: Direction 889 * 890 * Return: QDF_STATUS 891 */ 892 #ifdef QDF_OS_DEBUG 893 QDF_STATUS 894 __qdf_nbuf_map(qdf_device_t osdev, struct sk_buff *skb, qdf_dma_dir_t dir) 895 { 896 struct skb_shared_info *sh = skb_shinfo(skb); 897 898 qdf_assert((dir == QDF_DMA_TO_DEVICE) 899 || (dir == QDF_DMA_FROM_DEVICE)); 900 901 /* 902 * Assume there's only a single fragment. 903 * To support multiple fragments, it would be necessary to change 904 * qdf_nbuf_t to be a separate object that stores meta-info 905 * (including the bus address for each fragment) and a pointer 906 * to the underlying sk_buff. 907 */ 908 qdf_assert(sh->nr_frags == 0); 909 910 return __qdf_nbuf_map_single(osdev, skb, dir); 911 } 912 qdf_export_symbol(__qdf_nbuf_map); 913 914 #else 915 QDF_STATUS 916 __qdf_nbuf_map(qdf_device_t osdev, struct sk_buff *skb, qdf_dma_dir_t dir) 917 { 918 return __qdf_nbuf_map_single(osdev, skb, dir); 919 } 920 qdf_export_symbol(__qdf_nbuf_map); 921 #endif 922 /** 923 * __qdf_nbuf_unmap() - to unmap a previously mapped buf 924 * @osdev: OS device 925 * @skb: Pointer to network buffer 926 * @dir: dma direction 927 * 928 * Return: none 929 */ 930 void 931 __qdf_nbuf_unmap(qdf_device_t osdev, struct sk_buff *skb, 932 qdf_dma_dir_t dir) 933 { 934 qdf_assert((dir == QDF_DMA_TO_DEVICE) 935 || (dir == QDF_DMA_FROM_DEVICE)); 936 937 /* 938 * Assume there's a single fragment. 939 * If this is not true, the assertion in __qdf_nbuf_map will catch it. 940 */ 941 __qdf_nbuf_unmap_single(osdev, skb, dir); 942 } 943 qdf_export_symbol(__qdf_nbuf_unmap); 944 945 /** 946 * __qdf_nbuf_map_single() - map a single buffer to local bus address space 947 * @osdev: OS device 948 * @skb: Pointer to network buffer 949 * @dir: Direction 950 * 951 * Return: QDF_STATUS 952 */ 953 #if defined(A_SIMOS_DEVHOST) || defined(HIF_USB) || defined(HIF_SDIO) 954 QDF_STATUS 955 __qdf_nbuf_map_single(qdf_device_t osdev, qdf_nbuf_t buf, qdf_dma_dir_t dir) 956 { 957 qdf_dma_addr_t paddr; 958 959 QDF_NBUF_CB_PADDR(buf) = paddr = (uintptr_t)buf->data; 960 BUILD_BUG_ON(sizeof(paddr) < sizeof(buf->data)); 961 BUILD_BUG_ON(sizeof(QDF_NBUF_CB_PADDR(buf)) < sizeof(buf->data)); 962 return QDF_STATUS_SUCCESS; 963 } 964 qdf_export_symbol(__qdf_nbuf_map_single); 965 #else 966 QDF_STATUS 967 __qdf_nbuf_map_single(qdf_device_t osdev, qdf_nbuf_t buf, qdf_dma_dir_t dir) 968 { 969 qdf_dma_addr_t paddr; 970 971 /* assume that the OS only provides a single fragment */ 972 QDF_NBUF_CB_PADDR(buf) = paddr = 973 dma_map_single(osdev->dev, buf->data, 974 skb_end_pointer(buf) - buf->data, 975 __qdf_dma_dir_to_os(dir)); 976 return dma_mapping_error(osdev->dev, paddr) 977 ? QDF_STATUS_E_FAILURE 978 : QDF_STATUS_SUCCESS; 979 } 980 qdf_export_symbol(__qdf_nbuf_map_single); 981 #endif 982 /** 983 * __qdf_nbuf_unmap_single() - unmap a previously mapped buf 984 * @osdev: OS device 985 * @skb: Pointer to network buffer 986 * @dir: Direction 987 * 988 * Return: none 989 */ 990 #if defined(A_SIMOS_DEVHOST) || defined(HIF_USB) || defined(HIF_SDIO) 991 void __qdf_nbuf_unmap_single(qdf_device_t osdev, qdf_nbuf_t buf, 992 qdf_dma_dir_t dir) 993 { 994 } 995 #else 996 void __qdf_nbuf_unmap_single(qdf_device_t osdev, qdf_nbuf_t buf, 997 qdf_dma_dir_t dir) 998 { 999 if (QDF_NBUF_CB_PADDR(buf)) 1000 dma_unmap_single(osdev->dev, QDF_NBUF_CB_PADDR(buf), 1001 skb_end_pointer(buf) - buf->data, 1002 __qdf_dma_dir_to_os(dir)); 1003 } 1004 #endif 1005 qdf_export_symbol(__qdf_nbuf_unmap_single); 1006 1007 /** 1008 * __qdf_nbuf_set_rx_cksum() - set rx checksum 1009 * @skb: Pointer to network buffer 1010 * @cksum: Pointer to checksum value 1011 * 1012 * Return: QDF_STATUS 1013 */ 1014 QDF_STATUS 1015 __qdf_nbuf_set_rx_cksum(struct sk_buff *skb, qdf_nbuf_rx_cksum_t *cksum) 1016 { 1017 switch (cksum->l4_result) { 1018 case QDF_NBUF_RX_CKSUM_NONE: 1019 skb->ip_summed = CHECKSUM_NONE; 1020 break; 1021 case QDF_NBUF_RX_CKSUM_TCP_UDP_UNNECESSARY: 1022 skb->ip_summed = CHECKSUM_UNNECESSARY; 1023 break; 1024 case QDF_NBUF_RX_CKSUM_TCP_UDP_HW: 1025 skb->ip_summed = CHECKSUM_PARTIAL; 1026 skb->csum = cksum->val; 1027 break; 1028 default: 1029 pr_err("Unknown checksum type\n"); 1030 qdf_assert(0); 1031 return QDF_STATUS_E_NOSUPPORT; 1032 } 1033 return QDF_STATUS_SUCCESS; 1034 } 1035 qdf_export_symbol(__qdf_nbuf_set_rx_cksum); 1036 1037 /** 1038 * __qdf_nbuf_get_tx_cksum() - get tx checksum 1039 * @skb: Pointer to network buffer 1040 * 1041 * Return: TX checksum value 1042 */ 1043 qdf_nbuf_tx_cksum_t __qdf_nbuf_get_tx_cksum(struct sk_buff *skb) 1044 { 1045 switch (skb->ip_summed) { 1046 case CHECKSUM_NONE: 1047 return QDF_NBUF_TX_CKSUM_NONE; 1048 case CHECKSUM_PARTIAL: 1049 return QDF_NBUF_TX_CKSUM_TCP_UDP; 1050 case CHECKSUM_COMPLETE: 1051 return QDF_NBUF_TX_CKSUM_TCP_UDP_IP; 1052 default: 1053 return QDF_NBUF_TX_CKSUM_NONE; 1054 } 1055 } 1056 qdf_export_symbol(__qdf_nbuf_get_tx_cksum); 1057 1058 /** 1059 * __qdf_nbuf_get_tid() - get tid 1060 * @skb: Pointer to network buffer 1061 * 1062 * Return: tid 1063 */ 1064 uint8_t __qdf_nbuf_get_tid(struct sk_buff *skb) 1065 { 1066 return skb->priority; 1067 } 1068 qdf_export_symbol(__qdf_nbuf_get_tid); 1069 1070 /** 1071 * __qdf_nbuf_set_tid() - set tid 1072 * @skb: Pointer to network buffer 1073 * 1074 * Return: none 1075 */ 1076 void __qdf_nbuf_set_tid(struct sk_buff *skb, uint8_t tid) 1077 { 1078 skb->priority = tid; 1079 } 1080 qdf_export_symbol(__qdf_nbuf_set_tid); 1081 1082 /** 1083 * __qdf_nbuf_set_tid() - set tid 1084 * @skb: Pointer to network buffer 1085 * 1086 * Return: none 1087 */ 1088 uint8_t __qdf_nbuf_get_exemption_type(struct sk_buff *skb) 1089 { 1090 return QDF_NBUF_EXEMPT_NO_EXEMPTION; 1091 } 1092 qdf_export_symbol(__qdf_nbuf_get_exemption_type); 1093 1094 /** 1095 * __qdf_nbuf_reg_trace_cb() - register trace callback 1096 * @cb_func_ptr: Pointer to trace callback function 1097 * 1098 * Return: none 1099 */ 1100 void __qdf_nbuf_reg_trace_cb(qdf_nbuf_trace_update_t cb_func_ptr) 1101 { 1102 qdf_trace_update_cb = cb_func_ptr; 1103 } 1104 qdf_export_symbol(__qdf_nbuf_reg_trace_cb); 1105 1106 /** 1107 * __qdf_nbuf_data_get_dhcp_subtype() - get the subtype 1108 * of DHCP packet. 1109 * @data: Pointer to DHCP packet data buffer 1110 * 1111 * This func. returns the subtype of DHCP packet. 1112 * 1113 * Return: subtype of the DHCP packet. 1114 */ 1115 enum qdf_proto_subtype 1116 __qdf_nbuf_data_get_dhcp_subtype(uint8_t *data) 1117 { 1118 enum qdf_proto_subtype subtype = QDF_PROTO_INVALID; 1119 1120 if ((data[QDF_DHCP_OPTION53_OFFSET] == QDF_DHCP_OPTION53) && 1121 (data[QDF_DHCP_OPTION53_LENGTH_OFFSET] == 1122 QDF_DHCP_OPTION53_LENGTH)) { 1123 1124 switch (data[QDF_DHCP_OPTION53_STATUS_OFFSET]) { 1125 case QDF_DHCP_DISCOVER: 1126 subtype = QDF_PROTO_DHCP_DISCOVER; 1127 break; 1128 case QDF_DHCP_REQUEST: 1129 subtype = QDF_PROTO_DHCP_REQUEST; 1130 break; 1131 case QDF_DHCP_OFFER: 1132 subtype = QDF_PROTO_DHCP_OFFER; 1133 break; 1134 case QDF_DHCP_ACK: 1135 subtype = QDF_PROTO_DHCP_ACK; 1136 break; 1137 case QDF_DHCP_NAK: 1138 subtype = QDF_PROTO_DHCP_NACK; 1139 break; 1140 case QDF_DHCP_RELEASE: 1141 subtype = QDF_PROTO_DHCP_RELEASE; 1142 break; 1143 case QDF_DHCP_INFORM: 1144 subtype = QDF_PROTO_DHCP_INFORM; 1145 break; 1146 case QDF_DHCP_DECLINE: 1147 subtype = QDF_PROTO_DHCP_DECLINE; 1148 break; 1149 default: 1150 break; 1151 } 1152 } 1153 1154 return subtype; 1155 } 1156 1157 /** 1158 * __qdf_nbuf_data_get_eapol_subtype() - get the subtype 1159 * of EAPOL packet. 1160 * @data: Pointer to EAPOL packet data buffer 1161 * 1162 * This func. returns the subtype of EAPOL packet. 1163 * 1164 * Return: subtype of the EAPOL packet. 1165 */ 1166 enum qdf_proto_subtype 1167 __qdf_nbuf_data_get_eapol_subtype(uint8_t *data) 1168 { 1169 uint16_t eapol_key_info; 1170 enum qdf_proto_subtype subtype = QDF_PROTO_INVALID; 1171 uint16_t mask; 1172 1173 eapol_key_info = (uint16_t)(*(uint16_t *) 1174 (data + EAPOL_KEY_INFO_OFFSET)); 1175 1176 mask = eapol_key_info & EAPOL_MASK; 1177 switch (mask) { 1178 case EAPOL_M1_BIT_MASK: 1179 subtype = QDF_PROTO_EAPOL_M1; 1180 break; 1181 case EAPOL_M2_BIT_MASK: 1182 subtype = QDF_PROTO_EAPOL_M2; 1183 break; 1184 case EAPOL_M3_BIT_MASK: 1185 subtype = QDF_PROTO_EAPOL_M3; 1186 break; 1187 case EAPOL_M4_BIT_MASK: 1188 subtype = QDF_PROTO_EAPOL_M4; 1189 break; 1190 default: 1191 break; 1192 } 1193 1194 return subtype; 1195 } 1196 1197 /** 1198 * __qdf_nbuf_data_get_arp_subtype() - get the subtype 1199 * of ARP packet. 1200 * @data: Pointer to ARP packet data buffer 1201 * 1202 * This func. returns the subtype of ARP packet. 1203 * 1204 * Return: subtype of the ARP packet. 1205 */ 1206 enum qdf_proto_subtype 1207 __qdf_nbuf_data_get_arp_subtype(uint8_t *data) 1208 { 1209 uint16_t subtype; 1210 enum qdf_proto_subtype proto_subtype = QDF_PROTO_INVALID; 1211 1212 subtype = (uint16_t)(*(uint16_t *) 1213 (data + ARP_SUB_TYPE_OFFSET)); 1214 1215 switch (QDF_SWAP_U16(subtype)) { 1216 case ARP_REQUEST: 1217 proto_subtype = QDF_PROTO_ARP_REQ; 1218 break; 1219 case ARP_RESPONSE: 1220 proto_subtype = QDF_PROTO_ARP_RES; 1221 break; 1222 default: 1223 break; 1224 } 1225 1226 return proto_subtype; 1227 } 1228 1229 /** 1230 * __qdf_nbuf_data_get_icmp_subtype() - get the subtype 1231 * of IPV4 ICMP packet. 1232 * @data: Pointer to IPV4 ICMP packet data buffer 1233 * 1234 * This func. returns the subtype of ICMP packet. 1235 * 1236 * Return: subtype of the ICMP packet. 1237 */ 1238 enum qdf_proto_subtype 1239 __qdf_nbuf_data_get_icmp_subtype(uint8_t *data) 1240 { 1241 uint8_t subtype; 1242 enum qdf_proto_subtype proto_subtype = QDF_PROTO_INVALID; 1243 1244 subtype = (uint8_t)(*(uint8_t *) 1245 (data + ICMP_SUBTYPE_OFFSET)); 1246 1247 switch (subtype) { 1248 case ICMP_REQUEST: 1249 proto_subtype = QDF_PROTO_ICMP_REQ; 1250 break; 1251 case ICMP_RESPONSE: 1252 proto_subtype = QDF_PROTO_ICMP_RES; 1253 break; 1254 default: 1255 break; 1256 } 1257 1258 return proto_subtype; 1259 } 1260 1261 /** 1262 * __qdf_nbuf_data_get_icmpv6_subtype() - get the subtype 1263 * of IPV6 ICMPV6 packet. 1264 * @data: Pointer to IPV6 ICMPV6 packet data buffer 1265 * 1266 * This func. returns the subtype of ICMPV6 packet. 1267 * 1268 * Return: subtype of the ICMPV6 packet. 1269 */ 1270 enum qdf_proto_subtype 1271 __qdf_nbuf_data_get_icmpv6_subtype(uint8_t *data) 1272 { 1273 uint8_t subtype; 1274 enum qdf_proto_subtype proto_subtype = QDF_PROTO_INVALID; 1275 1276 subtype = (uint8_t)(*(uint8_t *) 1277 (data + ICMPV6_SUBTYPE_OFFSET)); 1278 1279 switch (subtype) { 1280 case ICMPV6_REQUEST: 1281 proto_subtype = QDF_PROTO_ICMPV6_REQ; 1282 break; 1283 case ICMPV6_RESPONSE: 1284 proto_subtype = QDF_PROTO_ICMPV6_RES; 1285 break; 1286 case ICMPV6_RS: 1287 proto_subtype = QDF_PROTO_ICMPV6_RS; 1288 break; 1289 case ICMPV6_RA: 1290 proto_subtype = QDF_PROTO_ICMPV6_RA; 1291 break; 1292 case ICMPV6_NS: 1293 proto_subtype = QDF_PROTO_ICMPV6_NS; 1294 break; 1295 case ICMPV6_NA: 1296 proto_subtype = QDF_PROTO_ICMPV6_NA; 1297 break; 1298 default: 1299 break; 1300 } 1301 1302 return proto_subtype; 1303 } 1304 1305 /** 1306 * __qdf_nbuf_data_get_ipv4_proto() - get the proto type 1307 * of IPV4 packet. 1308 * @data: Pointer to IPV4 packet data buffer 1309 * 1310 * This func. returns the proto type of IPV4 packet. 1311 * 1312 * Return: proto type of IPV4 packet. 1313 */ 1314 uint8_t 1315 __qdf_nbuf_data_get_ipv4_proto(uint8_t *data) 1316 { 1317 uint8_t proto_type; 1318 1319 proto_type = (uint8_t)(*(uint8_t *)(data + 1320 QDF_NBUF_TRAC_IPV4_PROTO_TYPE_OFFSET)); 1321 return proto_type; 1322 } 1323 1324 /** 1325 * __qdf_nbuf_data_get_ipv6_proto() - get the proto type 1326 * of IPV6 packet. 1327 * @data: Pointer to IPV6 packet data buffer 1328 * 1329 * This func. returns the proto type of IPV6 packet. 1330 * 1331 * Return: proto type of IPV6 packet. 1332 */ 1333 uint8_t 1334 __qdf_nbuf_data_get_ipv6_proto(uint8_t *data) 1335 { 1336 uint8_t proto_type; 1337 1338 proto_type = (uint8_t)(*(uint8_t *)(data + 1339 QDF_NBUF_TRAC_IPV6_PROTO_TYPE_OFFSET)); 1340 return proto_type; 1341 } 1342 1343 /** 1344 * __qdf_nbuf_data_is_ipv4_pkt() - check if packet is a ipv4 packet 1345 * @data: Pointer to network data 1346 * 1347 * This api is for Tx packets. 1348 * 1349 * Return: true if packet is ipv4 packet 1350 * false otherwise 1351 */ 1352 bool __qdf_nbuf_data_is_ipv4_pkt(uint8_t *data) 1353 { 1354 uint16_t ether_type; 1355 1356 ether_type = (uint16_t)(*(uint16_t *)(data + 1357 QDF_NBUF_TRAC_ETH_TYPE_OFFSET)); 1358 1359 if (ether_type == QDF_SWAP_U16(QDF_NBUF_TRAC_IPV4_ETH_TYPE)) 1360 return true; 1361 else 1362 return false; 1363 } 1364 qdf_export_symbol(__qdf_nbuf_data_is_ipv4_pkt); 1365 1366 /** 1367 * __qdf_nbuf_data_is_ipv4_dhcp_pkt() - check if skb data is a dhcp packet 1368 * @data: Pointer to network data buffer 1369 * 1370 * This api is for ipv4 packet. 1371 * 1372 * Return: true if packet is DHCP packet 1373 * false otherwise 1374 */ 1375 bool __qdf_nbuf_data_is_ipv4_dhcp_pkt(uint8_t *data) 1376 { 1377 uint16_t sport; 1378 uint16_t dport; 1379 1380 sport = (uint16_t)(*(uint16_t *)(data + QDF_NBUF_TRAC_IPV4_OFFSET + 1381 QDF_NBUF_TRAC_IPV4_HEADER_SIZE)); 1382 dport = (uint16_t)(*(uint16_t *)(data + QDF_NBUF_TRAC_IPV4_OFFSET + 1383 QDF_NBUF_TRAC_IPV4_HEADER_SIZE + 1384 sizeof(uint16_t))); 1385 1386 if (((sport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP_SRV_PORT)) && 1387 (dport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP_CLI_PORT))) || 1388 ((sport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP_CLI_PORT)) && 1389 (dport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP_SRV_PORT)))) 1390 return true; 1391 else 1392 return false; 1393 } 1394 qdf_export_symbol(__qdf_nbuf_data_is_ipv4_dhcp_pkt); 1395 1396 /** 1397 * __qdf_nbuf_data_is_ipv4_eapol_pkt() - check if skb data is a eapol packet 1398 * @data: Pointer to network data buffer 1399 * 1400 * This api is for ipv4 packet. 1401 * 1402 * Return: true if packet is EAPOL packet 1403 * false otherwise. 1404 */ 1405 bool __qdf_nbuf_data_is_ipv4_eapol_pkt(uint8_t *data) 1406 { 1407 uint16_t ether_type; 1408 1409 ether_type = (uint16_t)(*(uint16_t *)(data + 1410 QDF_NBUF_TRAC_ETH_TYPE_OFFSET)); 1411 1412 if (ether_type == QDF_SWAP_U16(QDF_NBUF_TRAC_EAPOL_ETH_TYPE)) 1413 return true; 1414 else 1415 return false; 1416 } 1417 qdf_export_symbol(__qdf_nbuf_data_is_ipv4_eapol_pkt); 1418 1419 /** 1420 * __qdf_nbuf_is_ipv4_wapi_pkt() - check if skb data is a wapi packet 1421 * @skb: Pointer to network buffer 1422 * 1423 * This api is for ipv4 packet. 1424 * 1425 * Return: true if packet is WAPI packet 1426 * false otherwise. 1427 */ 1428 bool __qdf_nbuf_is_ipv4_wapi_pkt(struct sk_buff *skb) 1429 { 1430 uint16_t ether_type; 1431 1432 ether_type = (uint16_t)(*(uint16_t *)(skb->data + 1433 QDF_NBUF_TRAC_ETH_TYPE_OFFSET)); 1434 1435 if (ether_type == QDF_SWAP_U16(QDF_NBUF_TRAC_WAPI_ETH_TYPE)) 1436 return true; 1437 else 1438 return false; 1439 } 1440 qdf_export_symbol(__qdf_nbuf_is_ipv4_wapi_pkt); 1441 1442 /** 1443 * __qdf_nbuf_is_ipv4_tdls_pkt() - check if skb data is a tdls packet 1444 * @skb: Pointer to network buffer 1445 * 1446 * This api is for ipv4 packet. 1447 * 1448 * Return: true if packet is tdls packet 1449 * false otherwise. 1450 */ 1451 bool __qdf_nbuf_is_ipv4_tdls_pkt(struct sk_buff *skb) 1452 { 1453 uint16_t ether_type; 1454 1455 ether_type = *(uint16_t *)(skb->data + 1456 QDF_NBUF_TRAC_ETH_TYPE_OFFSET); 1457 1458 if (ether_type == QDF_SWAP_U16(QDF_NBUF_TRAC_TDLS_ETH_TYPE)) 1459 return true; 1460 else 1461 return false; 1462 } 1463 qdf_export_symbol(__qdf_nbuf_is_ipv4_tdls_pkt); 1464 1465 /** 1466 * __qdf_nbuf_data_is_ipv4_arp_pkt() - check if skb data is a arp packet 1467 * @data: Pointer to network data buffer 1468 * 1469 * This api is for ipv4 packet. 1470 * 1471 * Return: true if packet is ARP packet 1472 * false otherwise. 1473 */ 1474 bool __qdf_nbuf_data_is_ipv4_arp_pkt(uint8_t *data) 1475 { 1476 uint16_t ether_type; 1477 1478 ether_type = (uint16_t)(*(uint16_t *)(data + 1479 QDF_NBUF_TRAC_ETH_TYPE_OFFSET)); 1480 1481 if (ether_type == QDF_SWAP_U16(QDF_NBUF_TRAC_ARP_ETH_TYPE)) 1482 return true; 1483 else 1484 return false; 1485 } 1486 qdf_export_symbol(__qdf_nbuf_data_is_ipv4_arp_pkt); 1487 1488 /** 1489 * __qdf_nbuf_data_is_arp_req() - check if skb data is a arp request 1490 * @data: Pointer to network data buffer 1491 * 1492 * This api is for ipv4 packet. 1493 * 1494 * Return: true if packet is ARP request 1495 * false otherwise. 1496 */ 1497 bool __qdf_nbuf_data_is_arp_req(uint8_t *data) 1498 { 1499 uint16_t op_code; 1500 1501 op_code = (uint16_t)(*(uint16_t *)(data + 1502 QDF_NBUF_PKT_ARP_OPCODE_OFFSET)); 1503 1504 if (op_code == QDF_SWAP_U16(QDF_NBUF_PKT_ARPOP_REQ)) 1505 return true; 1506 return false; 1507 } 1508 1509 /** 1510 * __qdf_nbuf_data_is_arp_rsp() - check if skb data is a arp response 1511 * @data: Pointer to network data buffer 1512 * 1513 * This api is for ipv4 packet. 1514 * 1515 * Return: true if packet is ARP response 1516 * false otherwise. 1517 */ 1518 bool __qdf_nbuf_data_is_arp_rsp(uint8_t *data) 1519 { 1520 uint16_t op_code; 1521 1522 op_code = (uint16_t)(*(uint16_t *)(data + 1523 QDF_NBUF_PKT_ARP_OPCODE_OFFSET)); 1524 1525 if (op_code == QDF_SWAP_U16(QDF_NBUF_PKT_ARPOP_REPLY)) 1526 return true; 1527 return false; 1528 } 1529 1530 /** 1531 * __qdf_nbuf_data_get_arp_src_ip() - get arp src IP 1532 * @data: Pointer to network data buffer 1533 * 1534 * This api is for ipv4 packet. 1535 * 1536 * Return: ARP packet source IP value. 1537 */ 1538 uint32_t __qdf_nbuf_get_arp_src_ip(uint8_t *data) 1539 { 1540 uint32_t src_ip; 1541 1542 src_ip = (uint32_t)(*(uint32_t *)(data + 1543 QDF_NBUF_PKT_ARP_SRC_IP_OFFSET)); 1544 1545 return src_ip; 1546 } 1547 1548 /** 1549 * __qdf_nbuf_data_get_arp_tgt_ip() - get arp target IP 1550 * @data: Pointer to network data buffer 1551 * 1552 * This api is for ipv4 packet. 1553 * 1554 * Return: ARP packet target IP value. 1555 */ 1556 uint32_t __qdf_nbuf_get_arp_tgt_ip(uint8_t *data) 1557 { 1558 uint32_t tgt_ip; 1559 1560 tgt_ip = (uint32_t)(*(uint32_t *)(data + 1561 QDF_NBUF_PKT_ARP_TGT_IP_OFFSET)); 1562 1563 return tgt_ip; 1564 } 1565 1566 /** 1567 * __qdf_nbuf_get_dns_domain_name() - get dns domain name 1568 * @data: Pointer to network data buffer 1569 * @len: length to copy 1570 * 1571 * This api is for dns domain name 1572 * 1573 * Return: dns domain name. 1574 */ 1575 uint8_t *__qdf_nbuf_get_dns_domain_name(uint8_t *data, uint32_t len) 1576 { 1577 uint8_t *domain_name; 1578 1579 domain_name = (uint8_t *) 1580 (data + QDF_NBUF_PKT_DNS_NAME_OVER_UDP_OFFSET); 1581 return domain_name; 1582 } 1583 1584 1585 /** 1586 * __qdf_nbuf_data_is_dns_query() - check if skb data is a dns query 1587 * @data: Pointer to network data buffer 1588 * 1589 * This api is for dns query packet. 1590 * 1591 * Return: true if packet is dns query packet. 1592 * false otherwise. 1593 */ 1594 bool __qdf_nbuf_data_is_dns_query(uint8_t *data) 1595 { 1596 uint16_t op_code; 1597 uint16_t tgt_port; 1598 1599 tgt_port = (uint16_t)(*(uint16_t *)(data + 1600 QDF_NBUF_PKT_DNS_DST_PORT_OFFSET)); 1601 /* Standard DNS query always happen on Dest Port 53. */ 1602 if (tgt_port == QDF_SWAP_U16(QDF_NBUF_PKT_DNS_STANDARD_PORT)) { 1603 op_code = (uint16_t)(*(uint16_t *)(data + 1604 QDF_NBUF_PKT_DNS_OVER_UDP_OPCODE_OFFSET)); 1605 if ((QDF_SWAP_U16(op_code) & QDF_NBUF_PKT_DNSOP_BITMAP) == 1606 QDF_NBUF_PKT_DNSOP_STANDARD_QUERY) 1607 return true; 1608 } 1609 return false; 1610 } 1611 1612 /** 1613 * __qdf_nbuf_data_is_dns_response() - check if skb data is a dns response 1614 * @data: Pointer to network data buffer 1615 * 1616 * This api is for dns query response. 1617 * 1618 * Return: true if packet is dns response packet. 1619 * false otherwise. 1620 */ 1621 bool __qdf_nbuf_data_is_dns_response(uint8_t *data) 1622 { 1623 uint16_t op_code; 1624 uint16_t src_port; 1625 1626 src_port = (uint16_t)(*(uint16_t *)(data + 1627 QDF_NBUF_PKT_DNS_SRC_PORT_OFFSET)); 1628 /* Standard DNS response always comes on Src Port 53. */ 1629 if (src_port == QDF_SWAP_U16(QDF_NBUF_PKT_DNS_STANDARD_PORT)) { 1630 op_code = (uint16_t)(*(uint16_t *)(data + 1631 QDF_NBUF_PKT_DNS_OVER_UDP_OPCODE_OFFSET)); 1632 1633 if ((QDF_SWAP_U16(op_code) & QDF_NBUF_PKT_DNSOP_BITMAP) == 1634 QDF_NBUF_PKT_DNSOP_STANDARD_RESPONSE) 1635 return true; 1636 } 1637 return false; 1638 } 1639 1640 /** 1641 * __qdf_nbuf_data_is_tcp_syn() - check if skb data is a tcp syn 1642 * @data: Pointer to network data buffer 1643 * 1644 * This api is for tcp syn packet. 1645 * 1646 * Return: true if packet is tcp syn packet. 1647 * false otherwise. 1648 */ 1649 bool __qdf_nbuf_data_is_tcp_syn(uint8_t *data) 1650 { 1651 uint8_t op_code; 1652 1653 op_code = (uint8_t)(*(uint8_t *)(data + 1654 QDF_NBUF_PKT_TCP_OPCODE_OFFSET)); 1655 1656 if (op_code == QDF_NBUF_PKT_TCPOP_SYN) 1657 return true; 1658 return false; 1659 } 1660 1661 /** 1662 * __qdf_nbuf_data_is_tcp_syn_ack() - check if skb data is a tcp syn ack 1663 * @data: Pointer to network data buffer 1664 * 1665 * This api is for tcp syn ack packet. 1666 * 1667 * Return: true if packet is tcp syn ack packet. 1668 * false otherwise. 1669 */ 1670 bool __qdf_nbuf_data_is_tcp_syn_ack(uint8_t *data) 1671 { 1672 uint8_t op_code; 1673 1674 op_code = (uint8_t)(*(uint8_t *)(data + 1675 QDF_NBUF_PKT_TCP_OPCODE_OFFSET)); 1676 1677 if (op_code == QDF_NBUF_PKT_TCPOP_SYN_ACK) 1678 return true; 1679 return false; 1680 } 1681 1682 /** 1683 * __qdf_nbuf_data_is_tcp_ack() - check if skb data is a tcp ack 1684 * @data: Pointer to network data buffer 1685 * 1686 * This api is for tcp ack packet. 1687 * 1688 * Return: true if packet is tcp ack packet. 1689 * false otherwise. 1690 */ 1691 bool __qdf_nbuf_data_is_tcp_ack(uint8_t *data) 1692 { 1693 uint8_t op_code; 1694 1695 op_code = (uint8_t)(*(uint8_t *)(data + 1696 QDF_NBUF_PKT_TCP_OPCODE_OFFSET)); 1697 1698 if (op_code == QDF_NBUF_PKT_TCPOP_ACK) 1699 return true; 1700 return false; 1701 } 1702 1703 /** 1704 * __qdf_nbuf_data_get_tcp_src_port() - get tcp src port 1705 * @data: Pointer to network data buffer 1706 * 1707 * This api is for tcp packet. 1708 * 1709 * Return: tcp source port value. 1710 */ 1711 uint16_t __qdf_nbuf_data_get_tcp_src_port(uint8_t *data) 1712 { 1713 uint16_t src_port; 1714 1715 src_port = (uint16_t)(*(uint16_t *)(data + 1716 QDF_NBUF_PKT_TCP_SRC_PORT_OFFSET)); 1717 1718 return src_port; 1719 } 1720 1721 /** 1722 * __qdf_nbuf_data_get_tcp_dst_port() - get tcp dst port 1723 * @data: Pointer to network data buffer 1724 * 1725 * This api is for tcp packet. 1726 * 1727 * Return: tcp destination port value. 1728 */ 1729 uint16_t __qdf_nbuf_data_get_tcp_dst_port(uint8_t *data) 1730 { 1731 uint16_t tgt_port; 1732 1733 tgt_port = (uint16_t)(*(uint16_t *)(data + 1734 QDF_NBUF_PKT_TCP_DST_PORT_OFFSET)); 1735 1736 return tgt_port; 1737 } 1738 1739 /** 1740 * __qdf_nbuf_data_is_icmpv4_req() - check if skb data is a icmpv4 request 1741 * @data: Pointer to network data buffer 1742 * 1743 * This api is for ipv4 req packet. 1744 * 1745 * Return: true if packet is icmpv4 request 1746 * false otherwise. 1747 */ 1748 bool __qdf_nbuf_data_is_icmpv4_req(uint8_t *data) 1749 { 1750 uint8_t op_code; 1751 1752 op_code = (uint8_t)(*(uint8_t *)(data + 1753 QDF_NBUF_PKT_ICMPv4_OPCODE_OFFSET)); 1754 1755 if (op_code == QDF_NBUF_PKT_ICMPv4OP_REQ) 1756 return true; 1757 return false; 1758 } 1759 1760 /** 1761 * __qdf_nbuf_data_is_icmpv4_rsp() - check if skb data is a icmpv4 res 1762 * @data: Pointer to network data buffer 1763 * 1764 * This api is for ipv4 res packet. 1765 * 1766 * Return: true if packet is icmpv4 response 1767 * false otherwise. 1768 */ 1769 bool __qdf_nbuf_data_is_icmpv4_rsp(uint8_t *data) 1770 { 1771 uint8_t op_code; 1772 1773 op_code = (uint8_t)(*(uint8_t *)(data + 1774 QDF_NBUF_PKT_ICMPv4_OPCODE_OFFSET)); 1775 1776 if (op_code == QDF_NBUF_PKT_ICMPv4OP_REPLY) 1777 return true; 1778 return false; 1779 } 1780 1781 /** 1782 * __qdf_nbuf_data_get_icmpv4_src_ip() - get icmpv4 src IP 1783 * @data: Pointer to network data buffer 1784 * 1785 * This api is for ipv4 packet. 1786 * 1787 * Return: icmpv4 packet source IP value. 1788 */ 1789 uint32_t __qdf_nbuf_get_icmpv4_src_ip(uint8_t *data) 1790 { 1791 uint32_t src_ip; 1792 1793 src_ip = (uint32_t)(*(uint32_t *)(data + 1794 QDF_NBUF_PKT_ICMPv4_SRC_IP_OFFSET)); 1795 1796 return src_ip; 1797 } 1798 1799 /** 1800 * __qdf_nbuf_data_get_icmpv4_tgt_ip() - get icmpv4 target IP 1801 * @data: Pointer to network data buffer 1802 * 1803 * This api is for ipv4 packet. 1804 * 1805 * Return: icmpv4 packet target IP value. 1806 */ 1807 uint32_t __qdf_nbuf_get_icmpv4_tgt_ip(uint8_t *data) 1808 { 1809 uint32_t tgt_ip; 1810 1811 tgt_ip = (uint32_t)(*(uint32_t *)(data + 1812 QDF_NBUF_PKT_ICMPv4_TGT_IP_OFFSET)); 1813 1814 return tgt_ip; 1815 } 1816 1817 1818 /** 1819 * __qdf_nbuf_data_is_ipv6_pkt() - check if it is IPV6 packet. 1820 * @data: Pointer to IPV6 packet data buffer 1821 * 1822 * This func. checks whether it is a IPV6 packet or not. 1823 * 1824 * Return: TRUE if it is a IPV6 packet 1825 * FALSE if not 1826 */ 1827 bool __qdf_nbuf_data_is_ipv6_pkt(uint8_t *data) 1828 { 1829 uint16_t ether_type; 1830 1831 ether_type = (uint16_t)(*(uint16_t *)(data + 1832 QDF_NBUF_TRAC_ETH_TYPE_OFFSET)); 1833 1834 if (ether_type == QDF_SWAP_U16(QDF_NBUF_TRAC_IPV6_ETH_TYPE)) 1835 return true; 1836 else 1837 return false; 1838 } 1839 qdf_export_symbol(__qdf_nbuf_data_is_ipv6_pkt); 1840 1841 /** 1842 * __qdf_nbuf_data_is_ipv6_dhcp_pkt() - check if skb data is a dhcp packet 1843 * @data: Pointer to network data buffer 1844 * 1845 * This api is for ipv6 packet. 1846 * 1847 * Return: true if packet is DHCP packet 1848 * false otherwise 1849 */ 1850 bool __qdf_nbuf_data_is_ipv6_dhcp_pkt(uint8_t *data) 1851 { 1852 uint16_t sport; 1853 uint16_t dport; 1854 1855 sport = *(uint16_t *)(data + QDF_NBUF_TRAC_IPV6_OFFSET + 1856 QDF_NBUF_TRAC_IPV6_HEADER_SIZE); 1857 dport = *(uint16_t *)(data + QDF_NBUF_TRAC_IPV6_OFFSET + 1858 QDF_NBUF_TRAC_IPV6_HEADER_SIZE + 1859 sizeof(uint16_t)); 1860 1861 if (((sport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP6_SRV_PORT)) && 1862 (dport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP6_CLI_PORT))) || 1863 ((sport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP6_CLI_PORT)) && 1864 (dport == QDF_SWAP_U16(QDF_NBUF_TRAC_DHCP6_SRV_PORT)))) 1865 return true; 1866 else 1867 return false; 1868 } 1869 qdf_export_symbol(__qdf_nbuf_data_is_ipv6_dhcp_pkt); 1870 1871 /** 1872 * __qdf_nbuf_data_is_ipv4_mcast_pkt() - check if it is IPV4 multicast packet. 1873 * @data: Pointer to IPV4 packet data buffer 1874 * 1875 * This func. checks whether it is a IPV4 multicast packet or not. 1876 * 1877 * Return: TRUE if it is a IPV4 multicast packet 1878 * FALSE if not 1879 */ 1880 bool __qdf_nbuf_data_is_ipv4_mcast_pkt(uint8_t *data) 1881 { 1882 if (__qdf_nbuf_data_is_ipv4_pkt(data)) { 1883 uint32_t *dst_addr = 1884 (uint32_t *)(data + QDF_NBUF_TRAC_IPV4_DEST_ADDR_OFFSET); 1885 1886 /* 1887 * Check first word of the IPV4 address and if it is 1888 * equal to 0xE then it represents multicast IP. 1889 */ 1890 if ((*dst_addr & QDF_NBUF_TRAC_IPV4_ADDR_BCAST_MASK) == 1891 QDF_NBUF_TRAC_IPV4_ADDR_MCAST_MASK) 1892 return true; 1893 else 1894 return false; 1895 } else 1896 return false; 1897 } 1898 1899 /** 1900 * __qdf_nbuf_data_is_ipv6_mcast_pkt() - check if it is IPV6 multicast packet. 1901 * @data: Pointer to IPV6 packet data buffer 1902 * 1903 * This func. checks whether it is a IPV6 multicast packet or not. 1904 * 1905 * Return: TRUE if it is a IPV6 multicast packet 1906 * FALSE if not 1907 */ 1908 bool __qdf_nbuf_data_is_ipv6_mcast_pkt(uint8_t *data) 1909 { 1910 if (__qdf_nbuf_data_is_ipv6_pkt(data)) { 1911 uint16_t *dst_addr; 1912 1913 dst_addr = (uint16_t *) 1914 (data + QDF_NBUF_TRAC_IPV6_DEST_ADDR_OFFSET); 1915 1916 /* 1917 * Check first byte of the IP address and if it 1918 * 0xFF00 then it is a IPV6 mcast packet. 1919 */ 1920 if (*dst_addr == 1921 QDF_SWAP_U16(QDF_NBUF_TRAC_IPV6_DEST_ADDR)) 1922 return true; 1923 else 1924 return false; 1925 } else 1926 return false; 1927 } 1928 1929 /** 1930 * __qdf_nbuf_data_is_icmp_pkt() - check if it is IPV4 ICMP packet. 1931 * @data: Pointer to IPV4 ICMP packet data buffer 1932 * 1933 * This func. checks whether it is a ICMP packet or not. 1934 * 1935 * Return: TRUE if it is a ICMP packet 1936 * FALSE if not 1937 */ 1938 bool __qdf_nbuf_data_is_icmp_pkt(uint8_t *data) 1939 { 1940 if (__qdf_nbuf_data_is_ipv4_pkt(data)) { 1941 uint8_t pkt_type; 1942 1943 pkt_type = (uint8_t)(*(uint8_t *)(data + 1944 QDF_NBUF_TRAC_IPV4_PROTO_TYPE_OFFSET)); 1945 1946 if (pkt_type == QDF_NBUF_TRAC_ICMP_TYPE) 1947 return true; 1948 else 1949 return false; 1950 } else 1951 return false; 1952 } 1953 1954 /** 1955 * __qdf_nbuf_data_is_icmpv6_pkt() - check if it is IPV6 ICMPV6 packet. 1956 * @data: Pointer to IPV6 ICMPV6 packet data buffer 1957 * 1958 * This func. checks whether it is a ICMPV6 packet or not. 1959 * 1960 * Return: TRUE if it is a ICMPV6 packet 1961 * FALSE if not 1962 */ 1963 bool __qdf_nbuf_data_is_icmpv6_pkt(uint8_t *data) 1964 { 1965 if (__qdf_nbuf_data_is_ipv6_pkt(data)) { 1966 uint8_t pkt_type; 1967 1968 pkt_type = (uint8_t)(*(uint8_t *)(data + 1969 QDF_NBUF_TRAC_IPV6_PROTO_TYPE_OFFSET)); 1970 1971 if (pkt_type == QDF_NBUF_TRAC_ICMPV6_TYPE) 1972 return true; 1973 else 1974 return false; 1975 } else 1976 return false; 1977 } 1978 1979 /** 1980 * __qdf_nbuf_data_is_ipv4_udp_pkt() - check if it is IPV4 UDP packet. 1981 * @data: Pointer to IPV4 UDP packet data buffer 1982 * 1983 * This func. checks whether it is a IPV4 UDP packet or not. 1984 * 1985 * Return: TRUE if it is a IPV4 UDP packet 1986 * FALSE if not 1987 */ 1988 bool __qdf_nbuf_data_is_ipv4_udp_pkt(uint8_t *data) 1989 { 1990 if (__qdf_nbuf_data_is_ipv4_pkt(data)) { 1991 uint8_t pkt_type; 1992 1993 pkt_type = (uint8_t)(*(uint8_t *)(data + 1994 QDF_NBUF_TRAC_IPV4_PROTO_TYPE_OFFSET)); 1995 1996 if (pkt_type == QDF_NBUF_TRAC_UDP_TYPE) 1997 return true; 1998 else 1999 return false; 2000 } else 2001 return false; 2002 } 2003 2004 /** 2005 * __qdf_nbuf_data_is_ipv4_tcp_pkt() - check if it is IPV4 TCP packet. 2006 * @data: Pointer to IPV4 TCP packet data buffer 2007 * 2008 * This func. checks whether it is a IPV4 TCP packet or not. 2009 * 2010 * Return: TRUE if it is a IPV4 TCP packet 2011 * FALSE if not 2012 */ 2013 bool __qdf_nbuf_data_is_ipv4_tcp_pkt(uint8_t *data) 2014 { 2015 if (__qdf_nbuf_data_is_ipv4_pkt(data)) { 2016 uint8_t pkt_type; 2017 2018 pkt_type = (uint8_t)(*(uint8_t *)(data + 2019 QDF_NBUF_TRAC_IPV4_PROTO_TYPE_OFFSET)); 2020 2021 if (pkt_type == QDF_NBUF_TRAC_TCP_TYPE) 2022 return true; 2023 else 2024 return false; 2025 } else 2026 return false; 2027 } 2028 2029 /** 2030 * __qdf_nbuf_data_is_ipv6_udp_pkt() - check if it is IPV6 UDP packet. 2031 * @data: Pointer to IPV6 UDP packet data buffer 2032 * 2033 * This func. checks whether it is a IPV6 UDP packet or not. 2034 * 2035 * Return: TRUE if it is a IPV6 UDP packet 2036 * FALSE if not 2037 */ 2038 bool __qdf_nbuf_data_is_ipv6_udp_pkt(uint8_t *data) 2039 { 2040 if (__qdf_nbuf_data_is_ipv6_pkt(data)) { 2041 uint8_t pkt_type; 2042 2043 pkt_type = (uint8_t)(*(uint8_t *)(data + 2044 QDF_NBUF_TRAC_IPV6_PROTO_TYPE_OFFSET)); 2045 2046 if (pkt_type == QDF_NBUF_TRAC_UDP_TYPE) 2047 return true; 2048 else 2049 return false; 2050 } else 2051 return false; 2052 } 2053 2054 /** 2055 * __qdf_nbuf_data_is_ipv6_tcp_pkt() - check if it is IPV6 TCP packet. 2056 * @data: Pointer to IPV6 TCP packet data buffer 2057 * 2058 * This func. checks whether it is a IPV6 TCP packet or not. 2059 * 2060 * Return: TRUE if it is a IPV6 TCP packet 2061 * FALSE if not 2062 */ 2063 bool __qdf_nbuf_data_is_ipv6_tcp_pkt(uint8_t *data) 2064 { 2065 if (__qdf_nbuf_data_is_ipv6_pkt(data)) { 2066 uint8_t pkt_type; 2067 2068 pkt_type = (uint8_t)(*(uint8_t *)(data + 2069 QDF_NBUF_TRAC_IPV6_PROTO_TYPE_OFFSET)); 2070 2071 if (pkt_type == QDF_NBUF_TRAC_TCP_TYPE) 2072 return true; 2073 else 2074 return false; 2075 } else 2076 return false; 2077 } 2078 2079 /** 2080 * __qdf_nbuf_is_bcast_pkt() - is destination address broadcast 2081 * @nbuf - sk buff 2082 * 2083 * Return: true if packet is broadcast 2084 * false otherwise 2085 */ 2086 bool __qdf_nbuf_is_bcast_pkt(qdf_nbuf_t nbuf) 2087 { 2088 struct ethhdr *eh = (struct ethhdr *)qdf_nbuf_data(nbuf); 2089 return qdf_is_macaddr_broadcast((struct qdf_mac_addr *)eh->h_dest); 2090 } 2091 qdf_export_symbol(__qdf_nbuf_is_bcast_pkt); 2092 2093 #ifdef NBUF_MEMORY_DEBUG 2094 #define QDF_NET_BUF_TRACK_MAX_SIZE (1024) 2095 2096 /** 2097 * struct qdf_nbuf_track_t - Network buffer track structure 2098 * 2099 * @p_next: Pointer to next 2100 * @net_buf: Pointer to network buffer 2101 * @func_name: Function name 2102 * @line_num: Line number 2103 * @size: Size 2104 */ 2105 struct qdf_nbuf_track_t { 2106 struct qdf_nbuf_track_t *p_next; 2107 qdf_nbuf_t net_buf; 2108 char func_name[QDF_MEM_FUNC_NAME_SIZE]; 2109 uint32_t line_num; 2110 size_t size; 2111 }; 2112 2113 static spinlock_t g_qdf_net_buf_track_lock[QDF_NET_BUF_TRACK_MAX_SIZE]; 2114 typedef struct qdf_nbuf_track_t QDF_NBUF_TRACK; 2115 2116 static QDF_NBUF_TRACK *gp_qdf_net_buf_track_tbl[QDF_NET_BUF_TRACK_MAX_SIZE]; 2117 static struct kmem_cache *nbuf_tracking_cache; 2118 static QDF_NBUF_TRACK *qdf_net_buf_track_free_list; 2119 static spinlock_t qdf_net_buf_track_free_list_lock; 2120 static uint32_t qdf_net_buf_track_free_list_count; 2121 static uint32_t qdf_net_buf_track_used_list_count; 2122 static uint32_t qdf_net_buf_track_max_used; 2123 static uint32_t qdf_net_buf_track_max_free; 2124 static uint32_t qdf_net_buf_track_max_allocated; 2125 2126 /** 2127 * update_max_used() - update qdf_net_buf_track_max_used tracking variable 2128 * 2129 * tracks the max number of network buffers that the wlan driver was tracking 2130 * at any one time. 2131 * 2132 * Return: none 2133 */ 2134 static inline void update_max_used(void) 2135 { 2136 int sum; 2137 2138 if (qdf_net_buf_track_max_used < 2139 qdf_net_buf_track_used_list_count) 2140 qdf_net_buf_track_max_used = qdf_net_buf_track_used_list_count; 2141 sum = qdf_net_buf_track_free_list_count + 2142 qdf_net_buf_track_used_list_count; 2143 if (qdf_net_buf_track_max_allocated < sum) 2144 qdf_net_buf_track_max_allocated = sum; 2145 } 2146 2147 /** 2148 * update_max_free() - update qdf_net_buf_track_free_list_count 2149 * 2150 * tracks the max number tracking buffers kept in the freelist. 2151 * 2152 * Return: none 2153 */ 2154 static inline void update_max_free(void) 2155 { 2156 if (qdf_net_buf_track_max_free < 2157 qdf_net_buf_track_free_list_count) 2158 qdf_net_buf_track_max_free = qdf_net_buf_track_free_list_count; 2159 } 2160 2161 /** 2162 * qdf_nbuf_track_alloc() - allocate a cookie to track nbufs allocated by wlan 2163 * 2164 * This function pulls from a freelist if possible and uses kmem_cache_alloc. 2165 * This function also ads fexibility to adjust the allocation and freelist 2166 * scheems. 2167 * 2168 * Return: a pointer to an unused QDF_NBUF_TRACK structure may not be zeroed. 2169 */ 2170 static QDF_NBUF_TRACK *qdf_nbuf_track_alloc(void) 2171 { 2172 int flags = GFP_KERNEL; 2173 unsigned long irq_flag; 2174 QDF_NBUF_TRACK *new_node = NULL; 2175 2176 spin_lock_irqsave(&qdf_net_buf_track_free_list_lock, irq_flag); 2177 qdf_net_buf_track_used_list_count++; 2178 if (qdf_net_buf_track_free_list != NULL) { 2179 new_node = qdf_net_buf_track_free_list; 2180 qdf_net_buf_track_free_list = 2181 qdf_net_buf_track_free_list->p_next; 2182 qdf_net_buf_track_free_list_count--; 2183 } 2184 update_max_used(); 2185 spin_unlock_irqrestore(&qdf_net_buf_track_free_list_lock, irq_flag); 2186 2187 if (new_node != NULL) 2188 return new_node; 2189 2190 if (in_interrupt() || irqs_disabled() || in_atomic()) 2191 flags = GFP_ATOMIC; 2192 2193 return kmem_cache_alloc(nbuf_tracking_cache, flags); 2194 } 2195 2196 /* FREEQ_POOLSIZE initial and minimum desired freelist poolsize */ 2197 #define FREEQ_POOLSIZE 2048 2198 2199 /** 2200 * qdf_nbuf_track_free() - free the nbuf tracking cookie. 2201 * 2202 * Matches calls to qdf_nbuf_track_alloc. 2203 * Either frees the tracking cookie to kernel or an internal 2204 * freelist based on the size of the freelist. 2205 * 2206 * Return: none 2207 */ 2208 static void qdf_nbuf_track_free(QDF_NBUF_TRACK *node) 2209 { 2210 unsigned long irq_flag; 2211 2212 if (!node) 2213 return; 2214 2215 /* Try to shrink the freelist if free_list_count > than FREEQ_POOLSIZE 2216 * only shrink the freelist if it is bigger than twice the number of 2217 * nbufs in use. If the driver is stalling in a consistent bursty 2218 * fasion, this will keep 3/4 of thee allocations from the free list 2219 * while also allowing the system to recover memory as less frantic 2220 * traffic occurs. 2221 */ 2222 2223 spin_lock_irqsave(&qdf_net_buf_track_free_list_lock, irq_flag); 2224 2225 qdf_net_buf_track_used_list_count--; 2226 if (qdf_net_buf_track_free_list_count > FREEQ_POOLSIZE && 2227 (qdf_net_buf_track_free_list_count > 2228 qdf_net_buf_track_used_list_count << 1)) { 2229 kmem_cache_free(nbuf_tracking_cache, node); 2230 } else { 2231 node->p_next = qdf_net_buf_track_free_list; 2232 qdf_net_buf_track_free_list = node; 2233 qdf_net_buf_track_free_list_count++; 2234 } 2235 update_max_free(); 2236 spin_unlock_irqrestore(&qdf_net_buf_track_free_list_lock, irq_flag); 2237 } 2238 2239 /** 2240 * qdf_nbuf_track_prefill() - prefill the nbuf tracking cookie freelist 2241 * 2242 * Removes a 'warmup time' characteristic of the freelist. Prefilling 2243 * the freelist first makes it performant for the first iperf udp burst 2244 * as well as steady state. 2245 * 2246 * Return: None 2247 */ 2248 static void qdf_nbuf_track_prefill(void) 2249 { 2250 int i; 2251 QDF_NBUF_TRACK *node, *head; 2252 2253 /* prepopulate the freelist */ 2254 head = NULL; 2255 for (i = 0; i < FREEQ_POOLSIZE; i++) { 2256 node = qdf_nbuf_track_alloc(); 2257 if (node == NULL) 2258 continue; 2259 node->p_next = head; 2260 head = node; 2261 } 2262 while (head) { 2263 node = head->p_next; 2264 qdf_nbuf_track_free(head); 2265 head = node; 2266 } 2267 2268 /* prefilled buffers should not count as used */ 2269 qdf_net_buf_track_max_used = 0; 2270 } 2271 2272 /** 2273 * qdf_nbuf_track_memory_manager_create() - manager for nbuf tracking cookies 2274 * 2275 * This initializes the memory manager for the nbuf tracking cookies. Because 2276 * these cookies are all the same size and only used in this feature, we can 2277 * use a kmem_cache to provide tracking as well as to speed up allocations. 2278 * To avoid the overhead of allocating and freeing the buffers (including SLUB 2279 * features) a freelist is prepopulated here. 2280 * 2281 * Return: None 2282 */ 2283 static void qdf_nbuf_track_memory_manager_create(void) 2284 { 2285 spin_lock_init(&qdf_net_buf_track_free_list_lock); 2286 nbuf_tracking_cache = kmem_cache_create("qdf_nbuf_tracking_cache", 2287 sizeof(QDF_NBUF_TRACK), 2288 0, 0, NULL); 2289 2290 qdf_nbuf_track_prefill(); 2291 } 2292 2293 /** 2294 * qdf_nbuf_track_memory_manager_destroy() - manager for nbuf tracking cookies 2295 * 2296 * Empty the freelist and print out usage statistics when it is no longer 2297 * needed. Also the kmem_cache should be destroyed here so that it can warn if 2298 * any nbuf tracking cookies were leaked. 2299 * 2300 * Return: None 2301 */ 2302 static void qdf_nbuf_track_memory_manager_destroy(void) 2303 { 2304 QDF_NBUF_TRACK *node, *tmp; 2305 unsigned long irq_flag; 2306 2307 spin_lock_irqsave(&qdf_net_buf_track_free_list_lock, irq_flag); 2308 node = qdf_net_buf_track_free_list; 2309 2310 if (qdf_net_buf_track_max_used > FREEQ_POOLSIZE * 4) 2311 qdf_print("%s: unexpectedly large max_used count %d", 2312 __func__, qdf_net_buf_track_max_used); 2313 2314 if (qdf_net_buf_track_max_used < qdf_net_buf_track_max_allocated) 2315 qdf_print("%s: %d unused trackers were allocated", 2316 __func__, 2317 qdf_net_buf_track_max_allocated - 2318 qdf_net_buf_track_max_used); 2319 2320 if (qdf_net_buf_track_free_list_count > FREEQ_POOLSIZE && 2321 qdf_net_buf_track_free_list_count > 3*qdf_net_buf_track_max_used/4) 2322 qdf_print("%s: check freelist shrinking functionality", 2323 __func__); 2324 2325 QDF_TRACE(QDF_MODULE_ID_QDF, QDF_TRACE_LEVEL_INFO, 2326 "%s: %d residual freelist size", 2327 __func__, qdf_net_buf_track_free_list_count); 2328 2329 QDF_TRACE(QDF_MODULE_ID_QDF, QDF_TRACE_LEVEL_INFO, 2330 "%s: %d max freelist size observed", 2331 __func__, qdf_net_buf_track_max_free); 2332 2333 QDF_TRACE(QDF_MODULE_ID_QDF, QDF_TRACE_LEVEL_INFO, 2334 "%s: %d max buffers used observed", 2335 __func__, qdf_net_buf_track_max_used); 2336 2337 QDF_TRACE(QDF_MODULE_ID_QDF, QDF_TRACE_LEVEL_INFO, 2338 "%s: %d max buffers allocated observed", 2339 __func__, qdf_net_buf_track_max_allocated); 2340 2341 while (node) { 2342 tmp = node; 2343 node = node->p_next; 2344 kmem_cache_free(nbuf_tracking_cache, tmp); 2345 qdf_net_buf_track_free_list_count--; 2346 } 2347 2348 if (qdf_net_buf_track_free_list_count != 0) 2349 qdf_info("%d unfreed tracking memory lost in freelist", 2350 qdf_net_buf_track_free_list_count); 2351 2352 if (qdf_net_buf_track_used_list_count != 0) 2353 qdf_info("%d unfreed tracking memory still in use", 2354 qdf_net_buf_track_used_list_count); 2355 2356 spin_unlock_irqrestore(&qdf_net_buf_track_free_list_lock, irq_flag); 2357 kmem_cache_destroy(nbuf_tracking_cache); 2358 qdf_net_buf_track_free_list = NULL; 2359 } 2360 2361 /** 2362 * qdf_net_buf_debug_init() - initialize network buffer debug functionality 2363 * 2364 * QDF network buffer debug feature tracks all SKBs allocated by WLAN driver 2365 * in a hash table and when driver is unloaded it reports about leaked SKBs. 2366 * WLAN driver module whose allocated SKB is freed by network stack are 2367 * suppose to call qdf_net_buf_debug_release_skb() such that the SKB is not 2368 * reported as memory leak. 2369 * 2370 * Return: none 2371 */ 2372 void qdf_net_buf_debug_init(void) 2373 { 2374 uint32_t i; 2375 2376 qdf_atomic_set(&qdf_nbuf_history_index, -1); 2377 2378 qdf_nbuf_map_tracking_init(); 2379 qdf_nbuf_track_memory_manager_create(); 2380 2381 for (i = 0; i < QDF_NET_BUF_TRACK_MAX_SIZE; i++) { 2382 gp_qdf_net_buf_track_tbl[i] = NULL; 2383 spin_lock_init(&g_qdf_net_buf_track_lock[i]); 2384 } 2385 } 2386 qdf_export_symbol(qdf_net_buf_debug_init); 2387 2388 /** 2389 * qdf_net_buf_debug_init() - exit network buffer debug functionality 2390 * 2391 * Exit network buffer tracking debug functionality and log SKB memory leaks 2392 * As part of exiting the functionality, free the leaked memory and 2393 * cleanup the tracking buffers. 2394 * 2395 * Return: none 2396 */ 2397 void qdf_net_buf_debug_exit(void) 2398 { 2399 uint32_t i; 2400 uint32_t count = 0; 2401 unsigned long irq_flag; 2402 QDF_NBUF_TRACK *p_node; 2403 QDF_NBUF_TRACK *p_prev; 2404 2405 for (i = 0; i < QDF_NET_BUF_TRACK_MAX_SIZE; i++) { 2406 spin_lock_irqsave(&g_qdf_net_buf_track_lock[i], irq_flag); 2407 p_node = gp_qdf_net_buf_track_tbl[i]; 2408 while (p_node) { 2409 p_prev = p_node; 2410 p_node = p_node->p_next; 2411 count++; 2412 qdf_info("SKB buf memory Leak@ Func %s, @Line %d, size %zu, nbuf %pK", 2413 p_prev->func_name, p_prev->line_num, 2414 p_prev->size, p_prev->net_buf); 2415 qdf_nbuf_track_free(p_prev); 2416 } 2417 spin_unlock_irqrestore(&g_qdf_net_buf_track_lock[i], irq_flag); 2418 } 2419 2420 qdf_nbuf_track_memory_manager_destroy(); 2421 qdf_nbuf_map_tracking_deinit(); 2422 2423 #ifdef CONFIG_HALT_KMEMLEAK 2424 if (count) { 2425 qdf_err("%d SKBs leaked .. please fix the SKB leak", count); 2426 QDF_BUG(0); 2427 } 2428 #endif 2429 } 2430 qdf_export_symbol(qdf_net_buf_debug_exit); 2431 2432 /** 2433 * qdf_net_buf_debug_hash() - hash network buffer pointer 2434 * 2435 * Return: hash value 2436 */ 2437 static uint32_t qdf_net_buf_debug_hash(qdf_nbuf_t net_buf) 2438 { 2439 uint32_t i; 2440 2441 i = (uint32_t) (((uintptr_t) net_buf) >> 4); 2442 i += (uint32_t) (((uintptr_t) net_buf) >> 14); 2443 i &= (QDF_NET_BUF_TRACK_MAX_SIZE - 1); 2444 2445 return i; 2446 } 2447 2448 /** 2449 * qdf_net_buf_debug_look_up() - look up network buffer in debug hash table 2450 * 2451 * Return: If skb is found in hash table then return pointer to network buffer 2452 * else return %NULL 2453 */ 2454 static QDF_NBUF_TRACK *qdf_net_buf_debug_look_up(qdf_nbuf_t net_buf) 2455 { 2456 uint32_t i; 2457 QDF_NBUF_TRACK *p_node; 2458 2459 i = qdf_net_buf_debug_hash(net_buf); 2460 p_node = gp_qdf_net_buf_track_tbl[i]; 2461 2462 while (p_node) { 2463 if (p_node->net_buf == net_buf) 2464 return p_node; 2465 p_node = p_node->p_next; 2466 } 2467 2468 return NULL; 2469 } 2470 2471 /** 2472 * qdf_net_buf_debug_add_node() - store skb in debug hash table 2473 * 2474 * Return: none 2475 */ 2476 void qdf_net_buf_debug_add_node(qdf_nbuf_t net_buf, size_t size, 2477 const char *func_name, uint32_t line_num) 2478 { 2479 uint32_t i; 2480 unsigned long irq_flag; 2481 QDF_NBUF_TRACK *p_node; 2482 QDF_NBUF_TRACK *new_node; 2483 2484 new_node = qdf_nbuf_track_alloc(); 2485 2486 i = qdf_net_buf_debug_hash(net_buf); 2487 spin_lock_irqsave(&g_qdf_net_buf_track_lock[i], irq_flag); 2488 2489 p_node = qdf_net_buf_debug_look_up(net_buf); 2490 2491 if (p_node) { 2492 qdf_print("Double allocation of skb ! Already allocated from %pK %s %d current alloc from %pK %s %d", 2493 p_node->net_buf, p_node->func_name, p_node->line_num, 2494 net_buf, func_name, line_num); 2495 qdf_nbuf_track_free(new_node); 2496 } else { 2497 p_node = new_node; 2498 if (p_node) { 2499 p_node->net_buf = net_buf; 2500 qdf_str_lcopy(p_node->func_name, func_name, 2501 QDF_MEM_FUNC_NAME_SIZE); 2502 p_node->line_num = line_num; 2503 p_node->size = size; 2504 qdf_mem_skb_inc(size); 2505 p_node->p_next = gp_qdf_net_buf_track_tbl[i]; 2506 gp_qdf_net_buf_track_tbl[i] = p_node; 2507 } else 2508 qdf_print( 2509 "Mem alloc failed ! Could not track skb from %s %d of size %zu", 2510 func_name, line_num, size); 2511 } 2512 2513 spin_unlock_irqrestore(&g_qdf_net_buf_track_lock[i], irq_flag); 2514 } 2515 qdf_export_symbol(qdf_net_buf_debug_add_node); 2516 2517 void qdf_net_buf_debug_update_node(qdf_nbuf_t net_buf, const char *func_name, 2518 uint32_t line_num) 2519 { 2520 uint32_t i; 2521 unsigned long irq_flag; 2522 QDF_NBUF_TRACK *p_node; 2523 2524 i = qdf_net_buf_debug_hash(net_buf); 2525 spin_lock_irqsave(&g_qdf_net_buf_track_lock[i], irq_flag); 2526 2527 p_node = qdf_net_buf_debug_look_up(net_buf); 2528 2529 if (p_node) { 2530 qdf_str_lcopy(p_node->func_name, kbasename(func_name), 2531 QDF_MEM_FUNC_NAME_SIZE); 2532 p_node->line_num = line_num; 2533 } 2534 2535 spin_unlock_irqrestore(&g_qdf_net_buf_track_lock[i], irq_flag); 2536 } 2537 2538 qdf_export_symbol(qdf_net_buf_debug_update_node); 2539 2540 /** 2541 * qdf_net_buf_debug_delete_node() - remove skb from debug hash table 2542 * 2543 * Return: none 2544 */ 2545 void qdf_net_buf_debug_delete_node(qdf_nbuf_t net_buf) 2546 { 2547 uint32_t i; 2548 QDF_NBUF_TRACK *p_head; 2549 QDF_NBUF_TRACK *p_node = NULL; 2550 unsigned long irq_flag; 2551 QDF_NBUF_TRACK *p_prev; 2552 2553 i = qdf_net_buf_debug_hash(net_buf); 2554 spin_lock_irqsave(&g_qdf_net_buf_track_lock[i], irq_flag); 2555 2556 p_head = gp_qdf_net_buf_track_tbl[i]; 2557 2558 /* Unallocated SKB */ 2559 if (!p_head) 2560 goto done; 2561 2562 p_node = p_head; 2563 /* Found at head of the table */ 2564 if (p_head->net_buf == net_buf) { 2565 gp_qdf_net_buf_track_tbl[i] = p_node->p_next; 2566 goto done; 2567 } 2568 2569 /* Search in collision list */ 2570 while (p_node) { 2571 p_prev = p_node; 2572 p_node = p_node->p_next; 2573 if ((NULL != p_node) && (p_node->net_buf == net_buf)) { 2574 p_prev->p_next = p_node->p_next; 2575 break; 2576 } 2577 } 2578 2579 done: 2580 spin_unlock_irqrestore(&g_qdf_net_buf_track_lock[i], irq_flag); 2581 2582 if (p_node) { 2583 qdf_mem_skb_dec(p_node->size); 2584 qdf_nbuf_track_free(p_node); 2585 } else { 2586 qdf_print("Unallocated buffer ! Double free of net_buf %pK ?", 2587 net_buf); 2588 QDF_BUG(0); 2589 } 2590 } 2591 qdf_export_symbol(qdf_net_buf_debug_delete_node); 2592 2593 void qdf_net_buf_debug_acquire_skb(qdf_nbuf_t net_buf, 2594 const char *func_name, uint32_t line_num) 2595 { 2596 qdf_nbuf_t ext_list = qdf_nbuf_get_ext_list(net_buf); 2597 2598 while (ext_list) { 2599 /* 2600 * Take care to add if it is Jumbo packet connected using 2601 * frag_list 2602 */ 2603 qdf_nbuf_t next; 2604 2605 next = qdf_nbuf_queue_next(ext_list); 2606 qdf_net_buf_debug_add_node(ext_list, 0, func_name, line_num); 2607 ext_list = next; 2608 } 2609 qdf_net_buf_debug_add_node(net_buf, 0, func_name, line_num); 2610 } 2611 qdf_export_symbol(qdf_net_buf_debug_acquire_skb); 2612 2613 /** 2614 * qdf_net_buf_debug_release_skb() - release skb to avoid memory leak 2615 * @net_buf: Network buf holding head segment (single) 2616 * 2617 * WLAN driver module whose allocated SKB is freed by network stack are 2618 * suppose to call this API before returning SKB to network stack such 2619 * that the SKB is not reported as memory leak. 2620 * 2621 * Return: none 2622 */ 2623 void qdf_net_buf_debug_release_skb(qdf_nbuf_t net_buf) 2624 { 2625 qdf_nbuf_t ext_list = qdf_nbuf_get_ext_list(net_buf); 2626 2627 while (ext_list) { 2628 /* 2629 * Take care to free if it is Jumbo packet connected using 2630 * frag_list 2631 */ 2632 qdf_nbuf_t next; 2633 2634 next = qdf_nbuf_queue_next(ext_list); 2635 2636 if (qdf_nbuf_is_tso(ext_list) && 2637 qdf_nbuf_get_users(ext_list) > 1) { 2638 ext_list = next; 2639 continue; 2640 } 2641 2642 qdf_net_buf_debug_delete_node(ext_list); 2643 ext_list = next; 2644 } 2645 2646 if (qdf_nbuf_is_tso(net_buf) && qdf_nbuf_get_users(net_buf) > 1) 2647 return; 2648 2649 qdf_net_buf_debug_delete_node(net_buf); 2650 } 2651 qdf_export_symbol(qdf_net_buf_debug_release_skb); 2652 2653 qdf_nbuf_t qdf_nbuf_alloc_debug(qdf_device_t osdev, qdf_size_t size, 2654 int reserve, int align, int prio, 2655 const char *func, uint32_t line) 2656 { 2657 qdf_nbuf_t nbuf; 2658 2659 nbuf = __qdf_nbuf_alloc(osdev, size, reserve, align, prio, func, line); 2660 2661 /* Store SKB in internal QDF tracking table */ 2662 if (qdf_likely(nbuf)) { 2663 qdf_net_buf_debug_add_node(nbuf, size, func, line); 2664 qdf_nbuf_history_add(nbuf, func, line, QDF_NBUF_ALLOC); 2665 } else { 2666 qdf_nbuf_history_add(nbuf, func, line, QDF_NBUF_ALLOC_FAILURE); 2667 } 2668 2669 return nbuf; 2670 } 2671 qdf_export_symbol(qdf_nbuf_alloc_debug); 2672 2673 void qdf_nbuf_free_debug(qdf_nbuf_t nbuf, const char *func, uint32_t line) 2674 { 2675 if (qdf_unlikely(!nbuf)) 2676 return; 2677 2678 if (qdf_nbuf_is_tso(nbuf) && qdf_nbuf_get_users(nbuf) > 1) 2679 goto free_buf; 2680 2681 /* Remove SKB from internal QDF tracking table */ 2682 qdf_nbuf_panic_on_free_if_mapped(nbuf, func, line); 2683 qdf_net_buf_debug_delete_node(nbuf); 2684 qdf_nbuf_history_add(nbuf, func, line, QDF_NBUF_FREE); 2685 2686 free_buf: 2687 __qdf_nbuf_free(nbuf); 2688 } 2689 qdf_export_symbol(qdf_nbuf_free_debug); 2690 2691 #endif /* NBUF_MEMORY_DEBUG */ 2692 2693 #if defined(FEATURE_TSO) 2694 2695 /** 2696 * struct qdf_tso_cmn_seg_info_t - TSO common info structure 2697 * 2698 * @ethproto: ethernet type of the msdu 2699 * @ip_tcp_hdr_len: ip + tcp length for the msdu 2700 * @l2_len: L2 length for the msdu 2701 * @eit_hdr: pointer to EIT header 2702 * @eit_hdr_len: EIT header length for the msdu 2703 * @eit_hdr_dma_map_addr: dma addr for EIT header 2704 * @tcphdr: pointer to tcp header 2705 * @ipv4_csum_en: ipv4 checksum enable 2706 * @tcp_ipv4_csum_en: TCP ipv4 checksum enable 2707 * @tcp_ipv6_csum_en: TCP ipv6 checksum enable 2708 * @ip_id: IP id 2709 * @tcp_seq_num: TCP sequence number 2710 * 2711 * This structure holds the TSO common info that is common 2712 * across all the TCP segments of the jumbo packet. 2713 */ 2714 struct qdf_tso_cmn_seg_info_t { 2715 uint16_t ethproto; 2716 uint16_t ip_tcp_hdr_len; 2717 uint16_t l2_len; 2718 uint8_t *eit_hdr; 2719 uint32_t eit_hdr_len; 2720 qdf_dma_addr_t eit_hdr_dma_map_addr; 2721 struct tcphdr *tcphdr; 2722 uint16_t ipv4_csum_en; 2723 uint16_t tcp_ipv4_csum_en; 2724 uint16_t tcp_ipv6_csum_en; 2725 uint16_t ip_id; 2726 uint32_t tcp_seq_num; 2727 }; 2728 2729 /** 2730 * __qdf_nbuf_get_tso_cmn_seg_info() - get TSO common 2731 * information 2732 * @osdev: qdf device handle 2733 * @skb: skb buffer 2734 * @tso_info: Parameters common to all segements 2735 * 2736 * Get the TSO information that is common across all the TCP 2737 * segments of the jumbo packet 2738 * 2739 * Return: 0 - success 1 - failure 2740 */ 2741 static uint8_t __qdf_nbuf_get_tso_cmn_seg_info(qdf_device_t osdev, 2742 struct sk_buff *skb, 2743 struct qdf_tso_cmn_seg_info_t *tso_info) 2744 { 2745 /* Get ethernet type and ethernet header length */ 2746 tso_info->ethproto = vlan_get_protocol(skb); 2747 2748 /* Determine whether this is an IPv4 or IPv6 packet */ 2749 if (tso_info->ethproto == htons(ETH_P_IP)) { /* IPv4 */ 2750 /* for IPv4, get the IP ID and enable TCP and IP csum */ 2751 struct iphdr *ipv4_hdr = ip_hdr(skb); 2752 2753 tso_info->ip_id = ntohs(ipv4_hdr->id); 2754 tso_info->ipv4_csum_en = 1; 2755 tso_info->tcp_ipv4_csum_en = 1; 2756 if (qdf_unlikely(ipv4_hdr->protocol != IPPROTO_TCP)) { 2757 qdf_err("TSO IPV4 proto 0x%x not TCP", 2758 ipv4_hdr->protocol); 2759 return 1; 2760 } 2761 } else if (tso_info->ethproto == htons(ETH_P_IPV6)) { /* IPv6 */ 2762 /* for IPv6, enable TCP csum. No IP ID or IP csum */ 2763 tso_info->tcp_ipv6_csum_en = 1; 2764 } else { 2765 qdf_err("TSO: ethertype 0x%x is not supported!", 2766 tso_info->ethproto); 2767 return 1; 2768 } 2769 tso_info->l2_len = (skb_network_header(skb) - skb_mac_header(skb)); 2770 tso_info->tcphdr = tcp_hdr(skb); 2771 tso_info->tcp_seq_num = ntohl(tcp_hdr(skb)->seq); 2772 /* get pointer to the ethernet + IP + TCP header and their length */ 2773 tso_info->eit_hdr = skb->data; 2774 tso_info->eit_hdr_len = (skb_transport_header(skb) 2775 - skb_mac_header(skb)) + tcp_hdrlen(skb); 2776 tso_info->eit_hdr_dma_map_addr = dma_map_single(osdev->dev, 2777 tso_info->eit_hdr, 2778 tso_info->eit_hdr_len, 2779 DMA_TO_DEVICE); 2780 if (unlikely(dma_mapping_error(osdev->dev, 2781 tso_info->eit_hdr_dma_map_addr))) { 2782 qdf_err("DMA mapping error!"); 2783 qdf_assert(0); 2784 return 1; 2785 } 2786 2787 if (tso_info->ethproto == htons(ETH_P_IP)) { 2788 /* inlcude IPv4 header length for IPV4 (total length) */ 2789 tso_info->ip_tcp_hdr_len = 2790 tso_info->eit_hdr_len - tso_info->l2_len; 2791 } else if (tso_info->ethproto == htons(ETH_P_IPV6)) { 2792 /* exclude IPv6 header length for IPv6 (payload length) */ 2793 tso_info->ip_tcp_hdr_len = tcp_hdrlen(skb); 2794 } 2795 /* 2796 * The length of the payload (application layer data) is added to 2797 * tso_info->ip_tcp_hdr_len before passing it on to the msdu link ext 2798 * descriptor. 2799 */ 2800 2801 TSO_DEBUG("%s seq# %u eit hdr len %u l2 len %u skb len %u\n", __func__, 2802 tso_info->tcp_seq_num, 2803 tso_info->eit_hdr_len, 2804 tso_info->l2_len, 2805 skb->len); 2806 return 0; 2807 } 2808 2809 2810 /** 2811 * __qdf_nbuf_fill_tso_cmn_seg_info() - Init function for each TSO nbuf segment 2812 * 2813 * @curr_seg: Segment whose contents are initialized 2814 * @tso_cmn_info: Parameters common to all segements 2815 * 2816 * Return: None 2817 */ 2818 static inline void __qdf_nbuf_fill_tso_cmn_seg_info( 2819 struct qdf_tso_seg_elem_t *curr_seg, 2820 struct qdf_tso_cmn_seg_info_t *tso_cmn_info) 2821 { 2822 /* Initialize the flags to 0 */ 2823 memset(&curr_seg->seg, 0x0, sizeof(curr_seg->seg)); 2824 2825 /* 2826 * The following fields remain the same across all segments of 2827 * a jumbo packet 2828 */ 2829 curr_seg->seg.tso_flags.tso_enable = 1; 2830 curr_seg->seg.tso_flags.ipv4_checksum_en = 2831 tso_cmn_info->ipv4_csum_en; 2832 curr_seg->seg.tso_flags.tcp_ipv6_checksum_en = 2833 tso_cmn_info->tcp_ipv6_csum_en; 2834 curr_seg->seg.tso_flags.tcp_ipv4_checksum_en = 2835 tso_cmn_info->tcp_ipv4_csum_en; 2836 curr_seg->seg.tso_flags.tcp_flags_mask = 0x1FF; 2837 2838 /* The following fields change for the segments */ 2839 curr_seg->seg.tso_flags.ip_id = tso_cmn_info->ip_id; 2840 tso_cmn_info->ip_id++; 2841 2842 curr_seg->seg.tso_flags.syn = tso_cmn_info->tcphdr->syn; 2843 curr_seg->seg.tso_flags.rst = tso_cmn_info->tcphdr->rst; 2844 curr_seg->seg.tso_flags.psh = tso_cmn_info->tcphdr->psh; 2845 curr_seg->seg.tso_flags.ack = tso_cmn_info->tcphdr->ack; 2846 curr_seg->seg.tso_flags.urg = tso_cmn_info->tcphdr->urg; 2847 curr_seg->seg.tso_flags.ece = tso_cmn_info->tcphdr->ece; 2848 curr_seg->seg.tso_flags.cwr = tso_cmn_info->tcphdr->cwr; 2849 2850 curr_seg->seg.tso_flags.tcp_seq_num = tso_cmn_info->tcp_seq_num; 2851 2852 /* 2853 * First fragment for each segment always contains the ethernet, 2854 * IP and TCP header 2855 */ 2856 curr_seg->seg.tso_frags[0].vaddr = tso_cmn_info->eit_hdr; 2857 curr_seg->seg.tso_frags[0].length = tso_cmn_info->eit_hdr_len; 2858 curr_seg->seg.total_len = curr_seg->seg.tso_frags[0].length; 2859 curr_seg->seg.tso_frags[0].paddr = tso_cmn_info->eit_hdr_dma_map_addr; 2860 2861 TSO_DEBUG("%s %d eit hdr %pK eit_hdr_len %d tcp_seq_num %u tso_info->total_len %u\n", 2862 __func__, __LINE__, tso_cmn_info->eit_hdr, 2863 tso_cmn_info->eit_hdr_len, 2864 curr_seg->seg.tso_flags.tcp_seq_num, 2865 curr_seg->seg.total_len); 2866 qdf_tso_seg_dbg_record(curr_seg, TSOSEG_LOC_FILLCMNSEG); 2867 } 2868 2869 /** 2870 * __qdf_nbuf_get_tso_info() - function to divide a TSO nbuf 2871 * into segments 2872 * @nbuf: network buffer to be segmented 2873 * @tso_info: This is the output. The information about the 2874 * TSO segments will be populated within this. 2875 * 2876 * This function fragments a TCP jumbo packet into smaller 2877 * segments to be transmitted by the driver. It chains the TSO 2878 * segments created into a list. 2879 * 2880 * Return: number of TSO segments 2881 */ 2882 uint32_t __qdf_nbuf_get_tso_info(qdf_device_t osdev, struct sk_buff *skb, 2883 struct qdf_tso_info_t *tso_info) 2884 { 2885 /* common across all segments */ 2886 struct qdf_tso_cmn_seg_info_t tso_cmn_info; 2887 /* segment specific */ 2888 void *tso_frag_vaddr; 2889 qdf_dma_addr_t tso_frag_paddr = 0; 2890 uint32_t num_seg = 0; 2891 struct qdf_tso_seg_elem_t *curr_seg; 2892 struct qdf_tso_num_seg_elem_t *total_num_seg; 2893 struct skb_frag_struct *frag = NULL; 2894 uint32_t tso_frag_len = 0; /* tso segment's fragment length*/ 2895 uint32_t skb_frag_len = 0; /* skb's fragment length (contiguous memory)*/ 2896 uint32_t skb_proc = skb->len; /* bytes of skb pending processing */ 2897 uint32_t tso_seg_size = skb_shinfo(skb)->gso_size; 2898 int j = 0; /* skb fragment index */ 2899 2900 memset(&tso_cmn_info, 0x0, sizeof(tso_cmn_info)); 2901 total_num_seg = tso_info->tso_num_seg_list; 2902 curr_seg = tso_info->tso_seg_list; 2903 total_num_seg->num_seg.tso_cmn_num_seg = 0; 2904 2905 if (qdf_unlikely(__qdf_nbuf_get_tso_cmn_seg_info(osdev, 2906 skb, &tso_cmn_info))) { 2907 qdf_warn("TSO: error getting common segment info"); 2908 return 0; 2909 } 2910 2911 /* length of the first chunk of data in the skb */ 2912 skb_frag_len = skb_headlen(skb); 2913 2914 /* the 0th tso segment's 0th fragment always contains the EIT header */ 2915 /* update the remaining skb fragment length and TSO segment length */ 2916 skb_frag_len -= tso_cmn_info.eit_hdr_len; 2917 skb_proc -= tso_cmn_info.eit_hdr_len; 2918 2919 /* get the address to the next tso fragment */ 2920 tso_frag_vaddr = skb->data + tso_cmn_info.eit_hdr_len; 2921 /* get the length of the next tso fragment */ 2922 tso_frag_len = min(skb_frag_len, tso_seg_size); 2923 2924 if (tso_frag_len != 0) { 2925 tso_frag_paddr = dma_map_single(osdev->dev, 2926 tso_frag_vaddr, tso_frag_len, DMA_TO_DEVICE); 2927 } 2928 2929 if (unlikely(dma_mapping_error(osdev->dev, 2930 tso_frag_paddr))) { 2931 qdf_err("DMA mapping error!"); 2932 qdf_assert(0); 2933 return 0; 2934 } 2935 TSO_DEBUG("%s[%d] skb frag len %d tso frag len %d\n", __func__, 2936 __LINE__, skb_frag_len, tso_frag_len); 2937 num_seg = tso_info->num_segs; 2938 tso_info->num_segs = 0; 2939 tso_info->is_tso = 1; 2940 2941 while (num_seg && curr_seg) { 2942 int i = 1; /* tso fragment index */ 2943 uint8_t more_tso_frags = 1; 2944 2945 curr_seg->seg.num_frags = 0; 2946 tso_info->num_segs++; 2947 total_num_seg->num_seg.tso_cmn_num_seg++; 2948 2949 __qdf_nbuf_fill_tso_cmn_seg_info(curr_seg, 2950 &tso_cmn_info); 2951 2952 if (unlikely(skb_proc == 0)) 2953 return tso_info->num_segs; 2954 2955 curr_seg->seg.tso_flags.ip_len = tso_cmn_info.ip_tcp_hdr_len; 2956 curr_seg->seg.tso_flags.l2_len = tso_cmn_info.l2_len; 2957 /* frag len is added to ip_len in while loop below*/ 2958 2959 curr_seg->seg.num_frags++; 2960 2961 while (more_tso_frags) { 2962 if (tso_frag_len != 0) { 2963 curr_seg->seg.tso_frags[i].vaddr = 2964 tso_frag_vaddr; 2965 curr_seg->seg.tso_frags[i].length = 2966 tso_frag_len; 2967 curr_seg->seg.total_len += tso_frag_len; 2968 curr_seg->seg.tso_flags.ip_len += tso_frag_len; 2969 curr_seg->seg.num_frags++; 2970 skb_proc = skb_proc - tso_frag_len; 2971 2972 /* increment the TCP sequence number */ 2973 2974 tso_cmn_info.tcp_seq_num += tso_frag_len; 2975 curr_seg->seg.tso_frags[i].paddr = 2976 tso_frag_paddr; 2977 } 2978 2979 TSO_DEBUG("%s[%d] frag %d frag len %d total_len %u vaddr %pK\n", 2980 __func__, __LINE__, 2981 i, 2982 tso_frag_len, 2983 curr_seg->seg.total_len, 2984 curr_seg->seg.tso_frags[i].vaddr); 2985 2986 /* if there is no more data left in the skb */ 2987 if (!skb_proc) 2988 return tso_info->num_segs; 2989 2990 /* get the next payload fragment information */ 2991 /* check if there are more fragments in this segment */ 2992 if (tso_frag_len < tso_seg_size) { 2993 more_tso_frags = 1; 2994 if (tso_frag_len != 0) { 2995 tso_seg_size = tso_seg_size - 2996 tso_frag_len; 2997 i++; 2998 if (curr_seg->seg.num_frags == 2999 FRAG_NUM_MAX) { 3000 more_tso_frags = 0; 3001 /* 3002 * reset i and the tso 3003 * payload size 3004 */ 3005 i = 1; 3006 tso_seg_size = 3007 skb_shinfo(skb)-> 3008 gso_size; 3009 } 3010 } 3011 } else { 3012 more_tso_frags = 0; 3013 /* reset i and the tso payload size */ 3014 i = 1; 3015 tso_seg_size = skb_shinfo(skb)->gso_size; 3016 } 3017 3018 /* if the next fragment is contiguous */ 3019 if ((tso_frag_len != 0) && (tso_frag_len < skb_frag_len)) { 3020 tso_frag_vaddr = tso_frag_vaddr + tso_frag_len; 3021 skb_frag_len = skb_frag_len - tso_frag_len; 3022 tso_frag_len = min(skb_frag_len, tso_seg_size); 3023 3024 } else { /* the next fragment is not contiguous */ 3025 if (skb_shinfo(skb)->nr_frags == 0) { 3026 qdf_info("TSO: nr_frags == 0!"); 3027 qdf_assert(0); 3028 return 0; 3029 } 3030 if (j >= skb_shinfo(skb)->nr_frags) { 3031 qdf_info("TSO: nr_frags %d j %d", 3032 skb_shinfo(skb)->nr_frags, j); 3033 qdf_assert(0); 3034 return 0; 3035 } 3036 frag = &skb_shinfo(skb)->frags[j]; 3037 skb_frag_len = skb_frag_size(frag); 3038 tso_frag_len = min(skb_frag_len, tso_seg_size); 3039 tso_frag_vaddr = skb_frag_address_safe(frag); 3040 j++; 3041 } 3042 3043 TSO_DEBUG("%s[%d] skb frag len %d tso frag %d len tso_seg_size %d\n", 3044 __func__, __LINE__, skb_frag_len, tso_frag_len, 3045 tso_seg_size); 3046 3047 if (!(tso_frag_vaddr)) { 3048 TSO_DEBUG("%s: Fragment virtual addr is NULL", 3049 __func__); 3050 return 0; 3051 } 3052 3053 tso_frag_paddr = 3054 dma_map_single(osdev->dev, 3055 tso_frag_vaddr, 3056 tso_frag_len, 3057 DMA_TO_DEVICE); 3058 if (unlikely(dma_mapping_error(osdev->dev, 3059 tso_frag_paddr))) { 3060 qdf_err("DMA mapping error!"); 3061 qdf_assert(0); 3062 return 0; 3063 } 3064 } 3065 TSO_DEBUG("%s tcp_seq_num: %u", __func__, 3066 curr_seg->seg.tso_flags.tcp_seq_num); 3067 num_seg--; 3068 /* if TCP FIN flag was set, set it in the last segment */ 3069 if (!num_seg) 3070 curr_seg->seg.tso_flags.fin = tso_cmn_info.tcphdr->fin; 3071 3072 qdf_tso_seg_dbg_record(curr_seg, TSOSEG_LOC_GETINFO); 3073 curr_seg = curr_seg->next; 3074 } 3075 return tso_info->num_segs; 3076 } 3077 qdf_export_symbol(__qdf_nbuf_get_tso_info); 3078 3079 /** 3080 * __qdf_nbuf_unmap_tso_segment() - function to dma unmap TSO segment element 3081 * 3082 * @osdev: qdf device handle 3083 * @tso_seg: TSO segment element to be unmapped 3084 * @is_last_seg: whether this is last tso seg or not 3085 * 3086 * Return: none 3087 */ 3088 void __qdf_nbuf_unmap_tso_segment(qdf_device_t osdev, 3089 struct qdf_tso_seg_elem_t *tso_seg, 3090 bool is_last_seg) 3091 { 3092 uint32_t num_frags = 0; 3093 3094 if (tso_seg->seg.num_frags > 0) 3095 num_frags = tso_seg->seg.num_frags - 1; 3096 3097 /*Num of frags in a tso seg cannot be less than 2 */ 3098 if (num_frags < 1) { 3099 /* 3100 * If Num of frags is 1 in a tso seg but is_last_seg true, 3101 * this may happen when qdf_nbuf_get_tso_info failed, 3102 * do dma unmap for the 0th frag in this seg. 3103 */ 3104 if (is_last_seg && tso_seg->seg.num_frags == 1) 3105 goto last_seg_free_first_frag; 3106 3107 qdf_assert(0); 3108 qdf_err("ERROR: num of frags in a tso segment is %d", 3109 (num_frags + 1)); 3110 return; 3111 } 3112 3113 while (num_frags) { 3114 /*Do dma unmap the tso seg except the 0th frag */ 3115 if (0 == tso_seg->seg.tso_frags[num_frags].paddr) { 3116 qdf_err("ERROR: TSO seg frag %d mapped physical address is NULL", 3117 num_frags); 3118 qdf_assert(0); 3119 return; 3120 } 3121 dma_unmap_single(osdev->dev, 3122 tso_seg->seg.tso_frags[num_frags].paddr, 3123 tso_seg->seg.tso_frags[num_frags].length, 3124 __qdf_dma_dir_to_os(QDF_DMA_TO_DEVICE)); 3125 tso_seg->seg.tso_frags[num_frags].paddr = 0; 3126 num_frags--; 3127 qdf_tso_seg_dbg_record(tso_seg, TSOSEG_LOC_UNMAPTSO); 3128 } 3129 3130 last_seg_free_first_frag: 3131 if (is_last_seg) { 3132 /*Do dma unmap for the tso seg 0th frag */ 3133 if (0 == tso_seg->seg.tso_frags[0].paddr) { 3134 qdf_err("ERROR: TSO seg frag 0 mapped physical address is NULL"); 3135 qdf_assert(0); 3136 return; 3137 } 3138 dma_unmap_single(osdev->dev, 3139 tso_seg->seg.tso_frags[0].paddr, 3140 tso_seg->seg.tso_frags[0].length, 3141 __qdf_dma_dir_to_os(QDF_DMA_TO_DEVICE)); 3142 tso_seg->seg.tso_frags[0].paddr = 0; 3143 qdf_tso_seg_dbg_record(tso_seg, TSOSEG_LOC_UNMAPLAST); 3144 } 3145 } 3146 qdf_export_symbol(__qdf_nbuf_unmap_tso_segment); 3147 3148 /** 3149 * __qdf_nbuf_get_tso_num_seg() - function to divide a TSO nbuf 3150 * into segments 3151 * @nbuf: network buffer to be segmented 3152 * @tso_info: This is the output. The information about the 3153 * TSO segments will be populated within this. 3154 * 3155 * This function fragments a TCP jumbo packet into smaller 3156 * segments to be transmitted by the driver. It chains the TSO 3157 * segments created into a list. 3158 * 3159 * Return: 0 - success, 1 - failure 3160 */ 3161 #ifndef BUILD_X86 3162 uint32_t __qdf_nbuf_get_tso_num_seg(struct sk_buff *skb) 3163 { 3164 uint32_t tso_seg_size = skb_shinfo(skb)->gso_size; 3165 uint32_t remainder, num_segs = 0; 3166 uint8_t skb_nr_frags = skb_shinfo(skb)->nr_frags; 3167 uint8_t frags_per_tso = 0; 3168 uint32_t skb_frag_len = 0; 3169 uint32_t eit_hdr_len = (skb_transport_header(skb) 3170 - skb_mac_header(skb)) + tcp_hdrlen(skb); 3171 struct skb_frag_struct *frag = NULL; 3172 int j = 0; 3173 uint32_t temp_num_seg = 0; 3174 3175 /* length of the first chunk of data in the skb minus eit header*/ 3176 skb_frag_len = skb_headlen(skb) - eit_hdr_len; 3177 3178 /* Calculate num of segs for skb's first chunk of data*/ 3179 remainder = skb_frag_len % tso_seg_size; 3180 num_segs = skb_frag_len / tso_seg_size; 3181 /** 3182 * Remainder non-zero and nr_frags zero implies end of skb data. 3183 * In that case, one more tso seg is required to accommodate 3184 * remaining data, hence num_segs++. If nr_frags is non-zero, 3185 * then remaining data will be accomodated while doing the calculation 3186 * for nr_frags data. Hence, frags_per_tso++. 3187 */ 3188 if (remainder) { 3189 if (!skb_nr_frags) 3190 num_segs++; 3191 else 3192 frags_per_tso++; 3193 } 3194 3195 while (skb_nr_frags) { 3196 if (j >= skb_shinfo(skb)->nr_frags) { 3197 qdf_info("TSO: nr_frags %d j %d", 3198 skb_shinfo(skb)->nr_frags, j); 3199 qdf_assert(0); 3200 return 0; 3201 } 3202 /** 3203 * Calculate the number of tso seg for nr_frags data: 3204 * Get the length of each frag in skb_frag_len, add to 3205 * remainder.Get the number of segments by dividing it to 3206 * tso_seg_size and calculate the new remainder. 3207 * Decrement the nr_frags value and keep 3208 * looping all the skb_fragments. 3209 */ 3210 frag = &skb_shinfo(skb)->frags[j]; 3211 skb_frag_len = skb_frag_size(frag); 3212 temp_num_seg = num_segs; 3213 remainder += skb_frag_len; 3214 num_segs += remainder / tso_seg_size; 3215 remainder = remainder % tso_seg_size; 3216 skb_nr_frags--; 3217 if (remainder) { 3218 if (num_segs > temp_num_seg) 3219 frags_per_tso = 0; 3220 /** 3221 * increment the tso per frags whenever remainder is 3222 * positive. If frags_per_tso reaches the (max-1), 3223 * [First frags always have EIT header, therefore max-1] 3224 * increment the num_segs as no more data can be 3225 * accomodated in the curr tso seg. Reset the remainder 3226 * and frags per tso and keep looping. 3227 */ 3228 frags_per_tso++; 3229 if (frags_per_tso == FRAG_NUM_MAX - 1) { 3230 num_segs++; 3231 frags_per_tso = 0; 3232 remainder = 0; 3233 } 3234 /** 3235 * If this is the last skb frag and still remainder is 3236 * non-zero(frags_per_tso is not reached to the max-1) 3237 * then increment the num_segs to take care of the 3238 * remaining length. 3239 */ 3240 if (!skb_nr_frags && remainder) { 3241 num_segs++; 3242 frags_per_tso = 0; 3243 } 3244 } else { 3245 /* Whenever remainder is 0, reset the frags_per_tso. */ 3246 frags_per_tso = 0; 3247 } 3248 j++; 3249 } 3250 3251 return num_segs; 3252 } 3253 #else 3254 uint32_t __qdf_nbuf_get_tso_num_seg(struct sk_buff *skb) 3255 { 3256 uint32_t i, gso_size, tmp_len, num_segs = 0; 3257 struct skb_frag_struct *frag = NULL; 3258 3259 /* 3260 * Check if the head SKB or any of frags are allocated in < 0x50000000 3261 * region which cannot be accessed by Target 3262 */ 3263 if (virt_to_phys(skb->data) < 0x50000040) { 3264 TSO_DEBUG("%s %d: Invalid Address nr_frags = %d, paddr = %pK \n", 3265 __func__, __LINE__, skb_shinfo(skb)->nr_frags, 3266 virt_to_phys(skb->data)); 3267 goto fail; 3268 3269 } 3270 3271 for (i = 0; i < skb_shinfo(skb)->nr_frags; i++) { 3272 frag = &skb_shinfo(skb)->frags[i]; 3273 3274 if (!frag) 3275 goto fail; 3276 3277 if (virt_to_phys(skb_frag_address_safe(frag)) < 0x50000040) 3278 goto fail; 3279 } 3280 3281 3282 gso_size = skb_shinfo(skb)->gso_size; 3283 tmp_len = skb->len - ((skb_transport_header(skb) - skb_mac_header(skb)) 3284 + tcp_hdrlen(skb)); 3285 while (tmp_len) { 3286 num_segs++; 3287 if (tmp_len > gso_size) 3288 tmp_len -= gso_size; 3289 else 3290 break; 3291 } 3292 3293 return num_segs; 3294 3295 /* 3296 * Do not free this frame, just do socket level accounting 3297 * so that this is not reused. 3298 */ 3299 fail: 3300 if (skb->sk) 3301 atomic_sub(skb->truesize, &(skb->sk->sk_wmem_alloc)); 3302 3303 return 0; 3304 } 3305 #endif 3306 qdf_export_symbol(__qdf_nbuf_get_tso_num_seg); 3307 3308 #endif /* FEATURE_TSO */ 3309 3310 /** 3311 * qdf_dmaaddr_to_32s - return high and low parts of dma_addr 3312 * 3313 * Returns the high and low 32-bits of the DMA addr in the provided ptrs 3314 * 3315 * Return: N/A 3316 */ 3317 void __qdf_dmaaddr_to_32s(qdf_dma_addr_t dmaaddr, 3318 uint32_t *lo, uint32_t *hi) 3319 { 3320 if (sizeof(dmaaddr) > sizeof(uint32_t)) { 3321 *lo = lower_32_bits(dmaaddr); 3322 *hi = upper_32_bits(dmaaddr); 3323 } else { 3324 *lo = dmaaddr; 3325 *hi = 0; 3326 } 3327 } 3328 3329 qdf_export_symbol(__qdf_dmaaddr_to_32s); 3330 3331 struct sk_buff *__qdf_nbuf_inc_users(struct sk_buff *skb) 3332 { 3333 qdf_nbuf_users_inc(&skb->users); 3334 return skb; 3335 } 3336 qdf_export_symbol(__qdf_nbuf_inc_users); 3337 3338 int __qdf_nbuf_get_users(struct sk_buff *skb) 3339 { 3340 return qdf_nbuf_users_read(&skb->users); 3341 } 3342 qdf_export_symbol(__qdf_nbuf_get_users); 3343 3344 /** 3345 * __qdf_nbuf_ref() - Reference the nbuf so it can get held until the last free. 3346 * @skb: sk_buff handle 3347 * 3348 * Return: none 3349 */ 3350 3351 void __qdf_nbuf_ref(struct sk_buff *skb) 3352 { 3353 skb_get(skb); 3354 } 3355 qdf_export_symbol(__qdf_nbuf_ref); 3356 3357 /** 3358 * __qdf_nbuf_shared() - Check whether the buffer is shared 3359 * @skb: sk_buff buffer 3360 * 3361 * Return: true if more than one person has a reference to this buffer. 3362 */ 3363 int __qdf_nbuf_shared(struct sk_buff *skb) 3364 { 3365 return skb_shared(skb); 3366 } 3367 qdf_export_symbol(__qdf_nbuf_shared); 3368 3369 /** 3370 * __qdf_nbuf_dmamap_create() - create a DMA map. 3371 * @osdev: qdf device handle 3372 * @dmap: dma map handle 3373 * 3374 * This can later be used to map networking buffers. They : 3375 * - need space in adf_drv's software descriptor 3376 * - are typically created during adf_drv_create 3377 * - need to be created before any API(qdf_nbuf_map) that uses them 3378 * 3379 * Return: QDF STATUS 3380 */ 3381 QDF_STATUS 3382 __qdf_nbuf_dmamap_create(qdf_device_t osdev, __qdf_dma_map_t *dmap) 3383 { 3384 QDF_STATUS error = QDF_STATUS_SUCCESS; 3385 /* 3386 * driver can tell its SG capablity, it must be handled. 3387 * Bounce buffers if they are there 3388 */ 3389 (*dmap) = kzalloc(sizeof(struct __qdf_dma_map), GFP_KERNEL); 3390 if (!(*dmap)) 3391 error = QDF_STATUS_E_NOMEM; 3392 3393 return error; 3394 } 3395 qdf_export_symbol(__qdf_nbuf_dmamap_create); 3396 /** 3397 * __qdf_nbuf_dmamap_destroy() - delete a dma map 3398 * @osdev: qdf device handle 3399 * @dmap: dma map handle 3400 * 3401 * Return: none 3402 */ 3403 void 3404 __qdf_nbuf_dmamap_destroy(qdf_device_t osdev, __qdf_dma_map_t dmap) 3405 { 3406 kfree(dmap); 3407 } 3408 qdf_export_symbol(__qdf_nbuf_dmamap_destroy); 3409 3410 /** 3411 * __qdf_nbuf_map_nbytes_single() - map nbytes 3412 * @osdev: os device 3413 * @buf: buffer 3414 * @dir: direction 3415 * @nbytes: number of bytes 3416 * 3417 * Return: QDF_STATUS 3418 */ 3419 #ifdef A_SIMOS_DEVHOST 3420 QDF_STATUS __qdf_nbuf_map_nbytes_single( 3421 qdf_device_t osdev, struct sk_buff *buf, 3422 qdf_dma_dir_t dir, int nbytes) 3423 { 3424 qdf_dma_addr_t paddr; 3425 3426 QDF_NBUF_CB_PADDR(buf) = paddr = buf->data; 3427 return QDF_STATUS_SUCCESS; 3428 } 3429 qdf_export_symbol(__qdf_nbuf_map_nbytes_single); 3430 #else 3431 QDF_STATUS __qdf_nbuf_map_nbytes_single( 3432 qdf_device_t osdev, struct sk_buff *buf, 3433 qdf_dma_dir_t dir, int nbytes) 3434 { 3435 qdf_dma_addr_t paddr; 3436 3437 /* assume that the OS only provides a single fragment */ 3438 QDF_NBUF_CB_PADDR(buf) = paddr = 3439 dma_map_single(osdev->dev, buf->data, 3440 nbytes, __qdf_dma_dir_to_os(dir)); 3441 return dma_mapping_error(osdev->dev, paddr) ? 3442 QDF_STATUS_E_FAULT : QDF_STATUS_SUCCESS; 3443 } 3444 qdf_export_symbol(__qdf_nbuf_map_nbytes_single); 3445 #endif 3446 /** 3447 * __qdf_nbuf_unmap_nbytes_single() - unmap nbytes 3448 * @osdev: os device 3449 * @buf: buffer 3450 * @dir: direction 3451 * @nbytes: number of bytes 3452 * 3453 * Return: none 3454 */ 3455 #if defined(A_SIMOS_DEVHOST) 3456 void 3457 __qdf_nbuf_unmap_nbytes_single( 3458 qdf_device_t osdev, struct sk_buff *buf, qdf_dma_dir_t dir, int nbytes) 3459 { 3460 } 3461 qdf_export_symbol(__qdf_nbuf_unmap_nbytes_single); 3462 3463 #else 3464 void 3465 __qdf_nbuf_unmap_nbytes_single( 3466 qdf_device_t osdev, struct sk_buff *buf, qdf_dma_dir_t dir, int nbytes) 3467 { 3468 if (0 == QDF_NBUF_CB_PADDR(buf)) { 3469 qdf_err("ERROR: NBUF mapped physical address is NULL"); 3470 return; 3471 } 3472 dma_unmap_single(osdev->dev, QDF_NBUF_CB_PADDR(buf), 3473 nbytes, __qdf_dma_dir_to_os(dir)); 3474 } 3475 qdf_export_symbol(__qdf_nbuf_unmap_nbytes_single); 3476 #endif 3477 /** 3478 * __qdf_nbuf_map_nbytes() - get the dma map of the nbuf 3479 * @osdev: os device 3480 * @skb: skb handle 3481 * @dir: dma direction 3482 * @nbytes: number of bytes to be mapped 3483 * 3484 * Return: QDF_STATUS 3485 */ 3486 #ifdef QDF_OS_DEBUG 3487 QDF_STATUS 3488 __qdf_nbuf_map_nbytes( 3489 qdf_device_t osdev, 3490 struct sk_buff *skb, 3491 qdf_dma_dir_t dir, 3492 int nbytes) 3493 { 3494 struct skb_shared_info *sh = skb_shinfo(skb); 3495 3496 qdf_assert((dir == QDF_DMA_TO_DEVICE) || (dir == QDF_DMA_FROM_DEVICE)); 3497 3498 /* 3499 * Assume there's only a single fragment. 3500 * To support multiple fragments, it would be necessary to change 3501 * adf_nbuf_t to be a separate object that stores meta-info 3502 * (including the bus address for each fragment) and a pointer 3503 * to the underlying sk_buff. 3504 */ 3505 qdf_assert(sh->nr_frags == 0); 3506 3507 return __qdf_nbuf_map_nbytes_single(osdev, skb, dir, nbytes); 3508 } 3509 qdf_export_symbol(__qdf_nbuf_map_nbytes); 3510 #else 3511 QDF_STATUS 3512 __qdf_nbuf_map_nbytes( 3513 qdf_device_t osdev, 3514 struct sk_buff *skb, 3515 qdf_dma_dir_t dir, 3516 int nbytes) 3517 { 3518 return __qdf_nbuf_map_nbytes_single(osdev, skb, dir, nbytes); 3519 } 3520 qdf_export_symbol(__qdf_nbuf_map_nbytes); 3521 #endif 3522 /** 3523 * __qdf_nbuf_unmap_nbytes() - to unmap a previously mapped buf 3524 * @osdev: OS device 3525 * @skb: skb handle 3526 * @dir: direction 3527 * @nbytes: number of bytes 3528 * 3529 * Return: none 3530 */ 3531 void 3532 __qdf_nbuf_unmap_nbytes( 3533 qdf_device_t osdev, 3534 struct sk_buff *skb, 3535 qdf_dma_dir_t dir, 3536 int nbytes) 3537 { 3538 qdf_assert((dir == QDF_DMA_TO_DEVICE) || (dir == QDF_DMA_FROM_DEVICE)); 3539 3540 /* 3541 * Assume there's a single fragment. 3542 * If this is not true, the assertion in __adf_nbuf_map will catch it. 3543 */ 3544 __qdf_nbuf_unmap_nbytes_single(osdev, skb, dir, nbytes); 3545 } 3546 qdf_export_symbol(__qdf_nbuf_unmap_nbytes); 3547 3548 /** 3549 * __qdf_nbuf_dma_map_info() - return the dma map info 3550 * @bmap: dma map 3551 * @sg: dma map info 3552 * 3553 * Return: none 3554 */ 3555 void 3556 __qdf_nbuf_dma_map_info(__qdf_dma_map_t bmap, qdf_dmamap_info_t *sg) 3557 { 3558 qdf_assert(bmap->mapped); 3559 qdf_assert(bmap->nsegs <= QDF_MAX_SCATTER); 3560 3561 memcpy(sg->dma_segs, bmap->seg, bmap->nsegs * 3562 sizeof(struct __qdf_segment)); 3563 sg->nsegs = bmap->nsegs; 3564 } 3565 qdf_export_symbol(__qdf_nbuf_dma_map_info); 3566 /** 3567 * __qdf_nbuf_frag_info() - return the frag data & len, where frag no. is 3568 * specified by the index 3569 * @skb: sk buff 3570 * @sg: scatter/gather list of all the frags 3571 * 3572 * Return: none 3573 */ 3574 #if defined(__QDF_SUPPORT_FRAG_MEM) 3575 void 3576 __qdf_nbuf_frag_info(struct sk_buff *skb, qdf_sglist_t *sg) 3577 { 3578 qdf_assert(skb != NULL); 3579 sg->sg_segs[0].vaddr = skb->data; 3580 sg->sg_segs[0].len = skb->len; 3581 sg->nsegs = 1; 3582 3583 for (int i = 1; i <= sh->nr_frags; i++) { 3584 skb_frag_t *f = &sh->frags[i - 1]; 3585 3586 sg->sg_segs[i].vaddr = (uint8_t *)(page_address(f->page) + 3587 f->page_offset); 3588 sg->sg_segs[i].len = f->size; 3589 3590 qdf_assert(i < QDF_MAX_SGLIST); 3591 } 3592 sg->nsegs += i; 3593 3594 } 3595 qdf_export_symbol(__qdf_nbuf_frag_info); 3596 #else 3597 #ifdef QDF_OS_DEBUG 3598 void 3599 __qdf_nbuf_frag_info(struct sk_buff *skb, qdf_sglist_t *sg) 3600 { 3601 3602 struct skb_shared_info *sh = skb_shinfo(skb); 3603 3604 qdf_assert(skb != NULL); 3605 sg->sg_segs[0].vaddr = skb->data; 3606 sg->sg_segs[0].len = skb->len; 3607 sg->nsegs = 1; 3608 3609 qdf_assert(sh->nr_frags == 0); 3610 } 3611 qdf_export_symbol(__qdf_nbuf_frag_info); 3612 #else 3613 void 3614 __qdf_nbuf_frag_info(struct sk_buff *skb, qdf_sglist_t *sg) 3615 { 3616 sg->sg_segs[0].vaddr = skb->data; 3617 sg->sg_segs[0].len = skb->len; 3618 sg->nsegs = 1; 3619 } 3620 qdf_export_symbol(__qdf_nbuf_frag_info); 3621 #endif 3622 #endif 3623 /** 3624 * __qdf_nbuf_get_frag_size() - get frag size 3625 * @nbuf: sk buffer 3626 * @cur_frag: current frag 3627 * 3628 * Return: frag size 3629 */ 3630 uint32_t 3631 __qdf_nbuf_get_frag_size(__qdf_nbuf_t nbuf, uint32_t cur_frag) 3632 { 3633 struct skb_shared_info *sh = skb_shinfo(nbuf); 3634 const skb_frag_t *frag = sh->frags + cur_frag; 3635 3636 return skb_frag_size(frag); 3637 } 3638 qdf_export_symbol(__qdf_nbuf_get_frag_size); 3639 3640 /** 3641 * __qdf_nbuf_frag_map() - dma map frag 3642 * @osdev: os device 3643 * @nbuf: sk buff 3644 * @offset: offset 3645 * @dir: direction 3646 * @cur_frag: current fragment 3647 * 3648 * Return: QDF status 3649 */ 3650 #ifdef A_SIMOS_DEVHOST 3651 QDF_STATUS __qdf_nbuf_frag_map( 3652 qdf_device_t osdev, __qdf_nbuf_t nbuf, 3653 int offset, qdf_dma_dir_t dir, int cur_frag) 3654 { 3655 int32_t paddr, frag_len; 3656 3657 QDF_NBUF_CB_PADDR(nbuf) = paddr = nbuf->data; 3658 return QDF_STATUS_SUCCESS; 3659 } 3660 qdf_export_symbol(__qdf_nbuf_frag_map); 3661 #else 3662 QDF_STATUS __qdf_nbuf_frag_map( 3663 qdf_device_t osdev, __qdf_nbuf_t nbuf, 3664 int offset, qdf_dma_dir_t dir, int cur_frag) 3665 { 3666 dma_addr_t paddr, frag_len; 3667 struct skb_shared_info *sh = skb_shinfo(nbuf); 3668 const skb_frag_t *frag = sh->frags + cur_frag; 3669 3670 frag_len = skb_frag_size(frag); 3671 3672 QDF_NBUF_CB_TX_EXTRA_FRAG_PADDR(nbuf) = paddr = 3673 skb_frag_dma_map(osdev->dev, frag, offset, frag_len, 3674 __qdf_dma_dir_to_os(dir)); 3675 return dma_mapping_error(osdev->dev, paddr) ? 3676 QDF_STATUS_E_FAULT : QDF_STATUS_SUCCESS; 3677 } 3678 qdf_export_symbol(__qdf_nbuf_frag_map); 3679 #endif 3680 /** 3681 * __qdf_nbuf_dmamap_set_cb() - setup the map callback for a dma map 3682 * @dmap: dma map 3683 * @cb: callback 3684 * @arg: argument 3685 * 3686 * Return: none 3687 */ 3688 void 3689 __qdf_nbuf_dmamap_set_cb(__qdf_dma_map_t dmap, void *cb, void *arg) 3690 { 3691 return; 3692 } 3693 qdf_export_symbol(__qdf_nbuf_dmamap_set_cb); 3694 3695 3696 /** 3697 * __qdf_nbuf_sync_single_for_cpu() - nbuf sync 3698 * @osdev: os device 3699 * @buf: sk buff 3700 * @dir: direction 3701 * 3702 * Return: none 3703 */ 3704 #if defined(A_SIMOS_DEVHOST) 3705 static void __qdf_nbuf_sync_single_for_cpu( 3706 qdf_device_t osdev, qdf_nbuf_t buf, qdf_dma_dir_t dir) 3707 { 3708 return; 3709 } 3710 #else 3711 static void __qdf_nbuf_sync_single_for_cpu( 3712 qdf_device_t osdev, qdf_nbuf_t buf, qdf_dma_dir_t dir) 3713 { 3714 if (0 == QDF_NBUF_CB_PADDR(buf)) { 3715 qdf_err("ERROR: NBUF mapped physical address is NULL"); 3716 return; 3717 } 3718 dma_sync_single_for_cpu(osdev->dev, QDF_NBUF_CB_PADDR(buf), 3719 skb_end_offset(buf) - skb_headroom(buf), 3720 __qdf_dma_dir_to_os(dir)); 3721 } 3722 #endif 3723 /** 3724 * __qdf_nbuf_sync_for_cpu() - nbuf sync 3725 * @osdev: os device 3726 * @skb: sk buff 3727 * @dir: direction 3728 * 3729 * Return: none 3730 */ 3731 void 3732 __qdf_nbuf_sync_for_cpu(qdf_device_t osdev, 3733 struct sk_buff *skb, qdf_dma_dir_t dir) 3734 { 3735 qdf_assert( 3736 (dir == QDF_DMA_TO_DEVICE) || (dir == QDF_DMA_FROM_DEVICE)); 3737 3738 /* 3739 * Assume there's a single fragment. 3740 * If this is not true, the assertion in __adf_nbuf_map will catch it. 3741 */ 3742 __qdf_nbuf_sync_single_for_cpu(osdev, skb, dir); 3743 } 3744 qdf_export_symbol(__qdf_nbuf_sync_for_cpu); 3745 3746 #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 10, 0)) 3747 /** 3748 * qdf_nbuf_update_radiotap_vht_flags() - Update radiotap header VHT flags 3749 * @rx_status: Pointer to rx_status. 3750 * @rtap_buf: Buf to which VHT info has to be updated. 3751 * @rtap_len: Current length of radiotap buffer 3752 * 3753 * Return: Length of radiotap after VHT flags updated. 3754 */ 3755 static unsigned int qdf_nbuf_update_radiotap_vht_flags( 3756 struct mon_rx_status *rx_status, 3757 int8_t *rtap_buf, 3758 uint32_t rtap_len) 3759 { 3760 uint16_t vht_flags = 0; 3761 3762 rtap_len = qdf_align(rtap_len, 2); 3763 3764 /* IEEE80211_RADIOTAP_VHT u16, u8, u8, u8[4], u8, u8, u16 */ 3765 vht_flags |= IEEE80211_RADIOTAP_VHT_KNOWN_STBC | 3766 IEEE80211_RADIOTAP_VHT_KNOWN_GI | 3767 IEEE80211_RADIOTAP_VHT_KNOWN_LDPC_EXTRA_OFDM_SYM | 3768 IEEE80211_RADIOTAP_VHT_KNOWN_BEAMFORMED | 3769 IEEE80211_RADIOTAP_VHT_KNOWN_BANDWIDTH | 3770 IEEE80211_RADIOTAP_VHT_KNOWN_GROUP_ID; 3771 put_unaligned_le16(vht_flags, &rtap_buf[rtap_len]); 3772 rtap_len += 2; 3773 3774 rtap_buf[rtap_len] |= 3775 (rx_status->is_stbc ? 3776 IEEE80211_RADIOTAP_VHT_FLAG_STBC : 0) | 3777 (rx_status->sgi ? IEEE80211_RADIOTAP_VHT_FLAG_SGI : 0) | 3778 (rx_status->ldpc ? 3779 IEEE80211_RADIOTAP_VHT_FLAG_LDPC_EXTRA_OFDM_SYM : 0) | 3780 (rx_status->beamformed ? 3781 IEEE80211_RADIOTAP_VHT_FLAG_BEAMFORMED : 0); 3782 rtap_len += 1; 3783 switch (rx_status->vht_flag_values2) { 3784 case IEEE80211_RADIOTAP_VHT_BW_20: 3785 rtap_buf[rtap_len] = RADIOTAP_VHT_BW_20; 3786 break; 3787 case IEEE80211_RADIOTAP_VHT_BW_40: 3788 rtap_buf[rtap_len] = RADIOTAP_VHT_BW_40; 3789 break; 3790 case IEEE80211_RADIOTAP_VHT_BW_80: 3791 rtap_buf[rtap_len] = RADIOTAP_VHT_BW_80; 3792 break; 3793 case IEEE80211_RADIOTAP_VHT_BW_160: 3794 rtap_buf[rtap_len] = RADIOTAP_VHT_BW_160; 3795 break; 3796 } 3797 rtap_len += 1; 3798 rtap_buf[rtap_len] = (rx_status->vht_flag_values3[0]); 3799 rtap_len += 1; 3800 rtap_buf[rtap_len] = (rx_status->vht_flag_values3[1]); 3801 rtap_len += 1; 3802 rtap_buf[rtap_len] = (rx_status->vht_flag_values3[2]); 3803 rtap_len += 1; 3804 rtap_buf[rtap_len] = (rx_status->vht_flag_values3[3]); 3805 rtap_len += 1; 3806 rtap_buf[rtap_len] = (rx_status->vht_flag_values4); 3807 rtap_len += 1; 3808 rtap_buf[rtap_len] = (rx_status->vht_flag_values5); 3809 rtap_len += 1; 3810 put_unaligned_le16(rx_status->vht_flag_values6, 3811 &rtap_buf[rtap_len]); 3812 rtap_len += 2; 3813 3814 return rtap_len; 3815 } 3816 3817 /** 3818 * qdf_nbuf_update_radiotap_he_flags() - Update radiotap header from rx_status 3819 * @rx_status: Pointer to rx_status. 3820 * @rtap_buf: buffer to which radiotap has to be updated 3821 * @rtap_len: radiotap length 3822 * 3823 * API update high-efficiency (11ax) fields in the radiotap header 3824 * 3825 * Return: length of rtap_len updated. 3826 */ 3827 static unsigned int 3828 qdf_nbuf_update_radiotap_he_flags(struct mon_rx_status *rx_status, 3829 int8_t *rtap_buf, uint32_t rtap_len) 3830 { 3831 /* 3832 * IEEE80211_RADIOTAP_HE u16, u16, u16, u16, u16, u16 3833 * Enable all "known" HE radiotap flags for now 3834 */ 3835 rtap_len = qdf_align(rtap_len, 2); 3836 3837 put_unaligned_le16(rx_status->he_data1, &rtap_buf[rtap_len]); 3838 rtap_len += 2; 3839 3840 put_unaligned_le16(rx_status->he_data2, &rtap_buf[rtap_len]); 3841 rtap_len += 2; 3842 3843 put_unaligned_le16(rx_status->he_data3, &rtap_buf[rtap_len]); 3844 rtap_len += 2; 3845 3846 put_unaligned_le16(rx_status->he_data4, &rtap_buf[rtap_len]); 3847 rtap_len += 2; 3848 3849 put_unaligned_le16(rx_status->he_data5, &rtap_buf[rtap_len]); 3850 rtap_len += 2; 3851 3852 put_unaligned_le16(rx_status->he_data6, &rtap_buf[rtap_len]); 3853 rtap_len += 2; 3854 qdf_debug("he data %x %x %x %x %x %x", 3855 rx_status->he_data1, 3856 rx_status->he_data2, rx_status->he_data3, 3857 rx_status->he_data4, rx_status->he_data5, 3858 rx_status->he_data6); 3859 return rtap_len; 3860 } 3861 3862 3863 /** 3864 * qdf_nbuf_update_radiotap_he_mu_flags() - update he-mu radiotap flags 3865 * @rx_status: Pointer to rx_status. 3866 * @rtap_buf: buffer to which radiotap has to be updated 3867 * @rtap_len: radiotap length 3868 * 3869 * API update HE-MU fields in the radiotap header 3870 * 3871 * Return: length of rtap_len updated. 3872 */ 3873 static unsigned int 3874 qdf_nbuf_update_radiotap_he_mu_flags(struct mon_rx_status *rx_status, 3875 int8_t *rtap_buf, uint32_t rtap_len) 3876 { 3877 rtap_len = qdf_align(rtap_len, 2); 3878 3879 /* 3880 * IEEE80211_RADIOTAP_HE_MU u16, u16, u8[4] 3881 * Enable all "known" he-mu radiotap flags for now 3882 */ 3883 put_unaligned_le16(rx_status->he_flags1, &rtap_buf[rtap_len]); 3884 rtap_len += 2; 3885 3886 put_unaligned_le16(rx_status->he_flags2, &rtap_buf[rtap_len]); 3887 rtap_len += 2; 3888 3889 rtap_buf[rtap_len] = rx_status->he_RU[0]; 3890 rtap_len += 1; 3891 3892 rtap_buf[rtap_len] = rx_status->he_RU[1]; 3893 rtap_len += 1; 3894 3895 rtap_buf[rtap_len] = rx_status->he_RU[2]; 3896 rtap_len += 1; 3897 3898 rtap_buf[rtap_len] = rx_status->he_RU[3]; 3899 rtap_len += 1; 3900 qdf_debug("he_flags %x %x he-RU %x %x %x %x", 3901 rx_status->he_flags1, 3902 rx_status->he_flags2, rx_status->he_RU[0], 3903 rx_status->he_RU[1], rx_status->he_RU[2], 3904 rx_status->he_RU[3]); 3905 3906 return rtap_len; 3907 } 3908 3909 /** 3910 * qdf_nbuf_update_radiotap_he_mu_other_flags() - update he_mu_other flags 3911 * @rx_status: Pointer to rx_status. 3912 * @rtap_buf: buffer to which radiotap has to be updated 3913 * @rtap_len: radiotap length 3914 * 3915 * API update he-mu-other fields in the radiotap header 3916 * 3917 * Return: length of rtap_len updated. 3918 */ 3919 static unsigned int 3920 qdf_nbuf_update_radiotap_he_mu_other_flags(struct mon_rx_status *rx_status, 3921 int8_t *rtap_buf, uint32_t rtap_len) 3922 { 3923 rtap_len = qdf_align(rtap_len, 2); 3924 3925 /* 3926 * IEEE80211_RADIOTAP_HE-MU-OTHER u16, u16, u8, u8 3927 * Enable all "known" he-mu-other radiotap flags for now 3928 */ 3929 put_unaligned_le16(rx_status->he_per_user_1, &rtap_buf[rtap_len]); 3930 rtap_len += 2; 3931 3932 put_unaligned_le16(rx_status->he_per_user_2, &rtap_buf[rtap_len]); 3933 rtap_len += 2; 3934 3935 rtap_buf[rtap_len] = rx_status->he_per_user_position; 3936 rtap_len += 1; 3937 3938 rtap_buf[rtap_len] = rx_status->he_per_user_known; 3939 rtap_len += 1; 3940 qdf_debug("he_per_user %x %x pos %x knwn %x", 3941 rx_status->he_per_user_1, 3942 rx_status->he_per_user_2, rx_status->he_per_user_position, 3943 rx_status->he_per_user_known); 3944 return rtap_len; 3945 } 3946 3947 3948 /** 3949 * This is the length for radiotap, combined length 3950 * (Mandatory part struct ieee80211_radiotap_header + RADIOTAP_HEADER_LEN) 3951 * cannot be more than available headroom_sz. 3952 * increase this when we add more radiotap elements. 3953 * Number after '+' indicates maximum possible increase due to alignment 3954 */ 3955 3956 #define RADIOTAP_VHT_FLAGS_LEN (12 + 1) 3957 #define RADIOTAP_HE_FLAGS_LEN (12 + 1) 3958 #define RADIOTAP_HE_MU_FLAGS_LEN (8 + 1) 3959 #define RADIOTAP_HE_MU_OTHER_FLAGS_LEN (18 + 1) 3960 #define RADIOTAP_FIXED_HEADER_LEN 17 3961 #define RADIOTAP_HT_FLAGS_LEN 3 3962 #define RADIOTAP_AMPDU_STATUS_LEN (8 + 3) 3963 #define RADIOTAP_VENDOR_NS_LEN \ 3964 (sizeof(struct qdf_radiotap_vendor_ns_ath) + 1) 3965 #define RADIOTAP_HEADER_LEN (sizeof(struct ieee80211_radiotap_header) + \ 3966 RADIOTAP_FIXED_HEADER_LEN + \ 3967 RADIOTAP_HT_FLAGS_LEN + \ 3968 RADIOTAP_VHT_FLAGS_LEN + \ 3969 RADIOTAP_AMPDU_STATUS_LEN + \ 3970 RADIOTAP_HE_FLAGS_LEN + \ 3971 RADIOTAP_HE_MU_FLAGS_LEN + \ 3972 RADIOTAP_HE_MU_OTHER_FLAGS_LEN + \ 3973 RADIOTAP_VENDOR_NS_LEN) 3974 3975 #define IEEE80211_RADIOTAP_HE 23 3976 #define IEEE80211_RADIOTAP_HE_MU 24 3977 #define IEEE80211_RADIOTAP_HE_MU_OTHER 25 3978 uint8_t ATH_OUI[] = {0x00, 0x03, 0x7f}; /* Atheros OUI */ 3979 3980 /** 3981 * radiotap_num_to_freq() - Get frequency from chan number 3982 * @chan_num - Input channel number 3983 * 3984 * Return - Channel frequency in Mhz 3985 */ 3986 static uint16_t radiotap_num_to_freq (uint16_t chan_num) 3987 { 3988 if (chan_num == CHANNEL_NUM_14) 3989 return CHANNEL_FREQ_2484; 3990 if (chan_num < CHANNEL_NUM_14) 3991 return CHANNEL_FREQ_2407 + 3992 (chan_num * FREQ_MULTIPLIER_CONST_5MHZ); 3993 3994 if (chan_num < CHANNEL_NUM_27) 3995 return CHANNEL_FREQ_2512 + 3996 ((chan_num - CHANNEL_NUM_15) * 3997 FREQ_MULTIPLIER_CONST_20MHZ); 3998 3999 if (chan_num > CHANNEL_NUM_182 && 4000 chan_num < CHANNEL_NUM_197) 4001 return ((chan_num * FREQ_MULTIPLIER_CONST_5MHZ) + 4002 CHANNEL_FREQ_4000); 4003 4004 return CHANNEL_FREQ_5000 + 4005 (chan_num * FREQ_MULTIPLIER_CONST_5MHZ); 4006 } 4007 4008 /** 4009 * qdf_nbuf_update_radiotap_ampdu_flags() - Update radiotap header ampdu flags 4010 * @rx_status: Pointer to rx_status. 4011 * @rtap_buf: Buf to which AMPDU info has to be updated. 4012 * @rtap_len: Current length of radiotap buffer 4013 * 4014 * Return: Length of radiotap after AMPDU flags updated. 4015 */ 4016 static unsigned int qdf_nbuf_update_radiotap_ampdu_flags( 4017 struct mon_rx_status *rx_status, 4018 uint8_t *rtap_buf, 4019 uint32_t rtap_len) 4020 { 4021 /* 4022 * IEEE80211_RADIOTAP_AMPDU_STATUS u32 u16 u8 u8 4023 * First 32 bits of AMPDU represents the reference number 4024 */ 4025 4026 uint32_t ampdu_reference_num = rx_status->ppdu_id; 4027 uint16_t ampdu_flags = 0; 4028 uint16_t ampdu_reserved_flags = 0; 4029 4030 rtap_len = qdf_align(rtap_len, 4); 4031 4032 put_unaligned_le32(ampdu_reference_num, &rtap_buf[rtap_len]); 4033 rtap_len += 4; 4034 put_unaligned_le16(ampdu_flags, &rtap_buf[rtap_len]); 4035 rtap_len += 2; 4036 put_unaligned_le16(ampdu_reserved_flags, &rtap_buf[rtap_len]); 4037 rtap_len += 2; 4038 4039 return rtap_len; 4040 } 4041 4042 /** 4043 * qdf_nbuf_update_radiotap() - Update radiotap header from rx_status 4044 * @rx_status: Pointer to rx_status. 4045 * @nbuf: nbuf pointer to which radiotap has to be updated 4046 * @headroom_sz: Available headroom size. 4047 * 4048 * Return: length of rtap_len updated. 4049 */ 4050 unsigned int qdf_nbuf_update_radiotap(struct mon_rx_status *rx_status, 4051 qdf_nbuf_t nbuf, uint32_t headroom_sz) 4052 { 4053 uint8_t rtap_buf[RADIOTAP_HEADER_LEN] = {0}; 4054 struct ieee80211_radiotap_header *rthdr = 4055 (struct ieee80211_radiotap_header *)rtap_buf; 4056 uint32_t rtap_hdr_len = sizeof(struct ieee80211_radiotap_header); 4057 uint32_t rtap_len = rtap_hdr_len; 4058 uint8_t length = rtap_len; 4059 struct qdf_radiotap_vendor_ns_ath *radiotap_vendor_ns_ath; 4060 4061 /* IEEE80211_RADIOTAP_TSFT __le64 microseconds*/ 4062 rthdr->it_present = (1 << IEEE80211_RADIOTAP_TSFT); 4063 put_unaligned_le64(rx_status->tsft, &rtap_buf[rtap_len]); 4064 rtap_len += 8; 4065 4066 /* IEEE80211_RADIOTAP_FLAGS u8 */ 4067 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_FLAGS); 4068 4069 if (rx_status->rs_fcs_err) 4070 rx_status->rtap_flags |= IEEE80211_RADIOTAP_F_BADFCS; 4071 4072 rtap_buf[rtap_len] = rx_status->rtap_flags; 4073 rtap_len += 1; 4074 4075 /* IEEE80211_RADIOTAP_RATE u8 500kb/s */ 4076 if (!rx_status->ht_flags && !rx_status->vht_flags && 4077 !rx_status->he_flags) { 4078 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_RATE); 4079 rtap_buf[rtap_len] = rx_status->rate; 4080 } else 4081 rtap_buf[rtap_len] = 0; 4082 rtap_len += 1; 4083 4084 /* IEEE80211_RADIOTAP_CHANNEL 2 x __le16 MHz, bitmap */ 4085 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_CHANNEL); 4086 rx_status->chan_freq = radiotap_num_to_freq(rx_status->chan_num); 4087 put_unaligned_le16(rx_status->chan_freq, &rtap_buf[rtap_len]); 4088 rtap_len += 2; 4089 /* Channel flags. */ 4090 if (rx_status->chan_num > CHANNEL_NUM_35) 4091 rx_status->chan_flags = RADIOTAP_5G_SPECTRUM_CHANNEL; 4092 else 4093 rx_status->chan_flags = RADIOTAP_2G_SPECTRUM_CHANNEL; 4094 if (rx_status->cck_flag) 4095 rx_status->chan_flags |= RADIOTAP_CCK_CHANNEL; 4096 if (rx_status->ofdm_flag) 4097 rx_status->chan_flags |= RADIOTAP_OFDM_CHANNEL; 4098 put_unaligned_le16(rx_status->chan_flags, &rtap_buf[rtap_len]); 4099 rtap_len += 2; 4100 4101 /* IEEE80211_RADIOTAP_DBM_ANTSIGNAL s8 decibels from one milliwatt 4102 * (dBm) 4103 */ 4104 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_DBM_ANTSIGNAL); 4105 /* 4106 * rssi_comb is int dB, need to convert it to dBm. 4107 * normalize value to noise floor of -96 dBm 4108 */ 4109 rtap_buf[rtap_len] = rx_status->rssi_comb + rx_status->chan_noise_floor; 4110 rtap_len += 1; 4111 4112 /* RX signal noise floor */ 4113 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_DBM_ANTNOISE); 4114 rtap_buf[rtap_len] = (uint8_t)rx_status->chan_noise_floor; 4115 rtap_len += 1; 4116 4117 /* IEEE80211_RADIOTAP_ANTENNA u8 antenna index */ 4118 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_ANTENNA); 4119 rtap_buf[rtap_len] = rx_status->nr_ant; 4120 rtap_len += 1; 4121 4122 if ((rtap_len - length) > RADIOTAP_FIXED_HEADER_LEN) { 4123 qdf_print("length is greater than RADIOTAP_FIXED_HEADER_LEN"); 4124 return 0; 4125 } 4126 4127 if (rx_status->ht_flags) { 4128 length = rtap_len; 4129 /* IEEE80211_RADIOTAP_VHT u8, u8, u8 */ 4130 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_MCS); 4131 rtap_buf[rtap_len] = IEEE80211_RADIOTAP_MCS_HAVE_BW | 4132 IEEE80211_RADIOTAP_MCS_HAVE_MCS | 4133 IEEE80211_RADIOTAP_MCS_HAVE_GI; 4134 rtap_len += 1; 4135 4136 if (rx_status->sgi) 4137 rtap_buf[rtap_len] |= IEEE80211_RADIOTAP_MCS_SGI; 4138 if (rx_status->bw) 4139 rtap_buf[rtap_len] |= IEEE80211_RADIOTAP_MCS_BW_40; 4140 else 4141 rtap_buf[rtap_len] |= IEEE80211_RADIOTAP_MCS_BW_20; 4142 rtap_len += 1; 4143 4144 rtap_buf[rtap_len] = rx_status->ht_mcs; 4145 rtap_len += 1; 4146 4147 if ((rtap_len - length) > RADIOTAP_HT_FLAGS_LEN) { 4148 qdf_print("length is greater than RADIOTAP_HT_FLAGS_LEN"); 4149 return 0; 4150 } 4151 } 4152 4153 if (rx_status->rs_flags & IEEE80211_AMPDU_FLAG) { 4154 /* IEEE80211_RADIOTAP_AMPDU_STATUS u32 u16 u8 u8 */ 4155 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_AMPDU_STATUS); 4156 rtap_len = qdf_nbuf_update_radiotap_ampdu_flags(rx_status, 4157 rtap_buf, 4158 rtap_len); 4159 } 4160 4161 if (rx_status->vht_flags) { 4162 length = rtap_len; 4163 /* IEEE80211_RADIOTAP_VHT u16, u8, u8, u8[4], u8, u8, u16 */ 4164 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_VHT); 4165 rtap_len = qdf_nbuf_update_radiotap_vht_flags(rx_status, 4166 rtap_buf, 4167 rtap_len); 4168 4169 if ((rtap_len - length) > RADIOTAP_VHT_FLAGS_LEN) { 4170 qdf_print("length is greater than RADIOTAP_VHT_FLAGS_LEN"); 4171 return 0; 4172 } 4173 } 4174 4175 if (rx_status->he_flags) { 4176 length = rtap_len; 4177 /* IEEE80211_RADIOTAP_HE */ 4178 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_HE); 4179 rtap_len = qdf_nbuf_update_radiotap_he_flags(rx_status, 4180 rtap_buf, 4181 rtap_len); 4182 4183 if ((rtap_len - length) > RADIOTAP_HE_FLAGS_LEN) { 4184 qdf_print("length is greater than RADIOTAP_HE_FLAGS_LEN"); 4185 return 0; 4186 } 4187 } 4188 4189 if (rx_status->he_mu_flags) { 4190 length = rtap_len; 4191 /* IEEE80211_RADIOTAP_HE-MU */ 4192 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_HE_MU); 4193 rtap_len = qdf_nbuf_update_radiotap_he_mu_flags(rx_status, 4194 rtap_buf, 4195 rtap_len); 4196 4197 if ((rtap_len - length) > RADIOTAP_HE_MU_FLAGS_LEN) { 4198 qdf_print("length is greater than RADIOTAP_HE_MU_FLAGS_LEN"); 4199 return 0; 4200 } 4201 } 4202 4203 if (rx_status->he_mu_other_flags) { 4204 length = rtap_len; 4205 /* IEEE80211_RADIOTAP_HE-MU-OTHER */ 4206 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_HE_MU_OTHER); 4207 rtap_len = 4208 qdf_nbuf_update_radiotap_he_mu_other_flags(rx_status, 4209 rtap_buf, 4210 rtap_len); 4211 4212 if ((rtap_len - length) > RADIOTAP_HE_MU_OTHER_FLAGS_LEN) { 4213 qdf_print("length is greater than RADIOTAP_HE_MU_OTHER_FLAGS_LEN"); 4214 return 0; 4215 } 4216 } 4217 4218 rtap_len = qdf_align(rtap_len, 2); 4219 /* 4220 * Radiotap Vendor Namespace 4221 */ 4222 rthdr->it_present |= (1 << IEEE80211_RADIOTAP_VENDOR_NAMESPACE); 4223 radiotap_vendor_ns_ath = (struct qdf_radiotap_vendor_ns_ath *) 4224 (rtap_buf + rtap_len); 4225 /* 4226 * Copy Atheros OUI - 3 bytes (4th byte is 0) 4227 */ 4228 qdf_mem_copy(radiotap_vendor_ns_ath->hdr.oui, ATH_OUI, sizeof(ATH_OUI)); 4229 /* 4230 * Name space selector = 0 4231 * We only will have one namespace for now 4232 */ 4233 radiotap_vendor_ns_ath->hdr.selector = 0; 4234 radiotap_vendor_ns_ath->hdr.skip_length = cpu_to_le16( 4235 sizeof(*radiotap_vendor_ns_ath) - 4236 sizeof(radiotap_vendor_ns_ath->hdr)); 4237 radiotap_vendor_ns_ath->device_id = cpu_to_le32(rx_status->device_id); 4238 radiotap_vendor_ns_ath->lsig = cpu_to_le32(rx_status->l_sig_a_info); 4239 radiotap_vendor_ns_ath->lsig_b = cpu_to_le32(rx_status->l_sig_b_info); 4240 radiotap_vendor_ns_ath->ppdu_start_timestamp = 4241 cpu_to_le32(rx_status->ppdu_timestamp); 4242 rtap_len += sizeof(*radiotap_vendor_ns_ath); 4243 4244 rthdr->it_len = cpu_to_le16(rtap_len); 4245 rthdr->it_present = cpu_to_le32(rthdr->it_present); 4246 4247 if (headroom_sz < rtap_len) { 4248 qdf_err("ERROR: not enough space to update radiotap"); 4249 return 0; 4250 } 4251 qdf_nbuf_push_head(nbuf, rtap_len); 4252 qdf_mem_copy(qdf_nbuf_data(nbuf), rtap_buf, rtap_len); 4253 return rtap_len; 4254 } 4255 #else 4256 static unsigned int qdf_nbuf_update_radiotap_vht_flags( 4257 struct mon_rx_status *rx_status, 4258 int8_t *rtap_buf, 4259 uint32_t rtap_len) 4260 { 4261 qdf_err("ERROR: struct ieee80211_radiotap_header not supported"); 4262 return 0; 4263 } 4264 4265 unsigned int qdf_nbuf_update_radiotap_he_flags(struct mon_rx_status *rx_status, 4266 int8_t *rtap_buf, uint32_t rtap_len) 4267 { 4268 qdf_err("ERROR: struct ieee80211_radiotap_header not supported"); 4269 return 0; 4270 } 4271 4272 static unsigned int qdf_nbuf_update_radiotap_ampdu_flags( 4273 struct mon_rx_status *rx_status, 4274 uint8_t *rtap_buf, 4275 uint32_t rtap_len) 4276 { 4277 qdf_err("ERROR: struct ieee80211_radiotap_header not supported"); 4278 return 0; 4279 } 4280 4281 unsigned int qdf_nbuf_update_radiotap(struct mon_rx_status *rx_status, 4282 qdf_nbuf_t nbuf, uint32_t headroom_sz) 4283 { 4284 qdf_err("ERROR: struct ieee80211_radiotap_header not supported"); 4285 return 0; 4286 } 4287 #endif 4288 qdf_export_symbol(qdf_nbuf_update_radiotap); 4289 4290 /** 4291 * __qdf_nbuf_reg_free_cb() - register nbuf free callback 4292 * @cb_func_ptr: function pointer to the nbuf free callback 4293 * 4294 * This function registers a callback function for nbuf free. 4295 * 4296 * Return: none 4297 */ 4298 void __qdf_nbuf_reg_free_cb(qdf_nbuf_free_t cb_func_ptr) 4299 { 4300 nbuf_free_cb = cb_func_ptr; 4301 } 4302 4303 /** 4304 * qdf_nbuf_classify_pkt() - classify packet 4305 * @skb - sk buff 4306 * 4307 * Return: none 4308 */ 4309 void qdf_nbuf_classify_pkt(struct sk_buff *skb) 4310 { 4311 struct ethhdr *eh = (struct ethhdr *)skb->data; 4312 4313 /* check destination mac address is broadcast/multicast */ 4314 if (is_broadcast_ether_addr((uint8_t *)eh)) 4315 QDF_NBUF_CB_SET_BCAST(skb); 4316 else if (is_multicast_ether_addr((uint8_t *)eh)) 4317 QDF_NBUF_CB_SET_MCAST(skb); 4318 4319 if (qdf_nbuf_is_ipv4_arp_pkt(skb)) 4320 QDF_NBUF_CB_GET_PACKET_TYPE(skb) = 4321 QDF_NBUF_CB_PACKET_TYPE_ARP; 4322 else if (qdf_nbuf_is_ipv4_dhcp_pkt(skb)) 4323 QDF_NBUF_CB_GET_PACKET_TYPE(skb) = 4324 QDF_NBUF_CB_PACKET_TYPE_DHCP; 4325 else if (qdf_nbuf_is_ipv4_eapol_pkt(skb)) 4326 QDF_NBUF_CB_GET_PACKET_TYPE(skb) = 4327 QDF_NBUF_CB_PACKET_TYPE_EAPOL; 4328 else if (qdf_nbuf_is_ipv4_wapi_pkt(skb)) 4329 QDF_NBUF_CB_GET_PACKET_TYPE(skb) = 4330 QDF_NBUF_CB_PACKET_TYPE_WAPI; 4331 } 4332 qdf_export_symbol(qdf_nbuf_classify_pkt); 4333 4334 void __qdf_nbuf_init(__qdf_nbuf_t nbuf) 4335 { 4336 qdf_nbuf_users_set(&nbuf->users, 1); 4337 nbuf->data = nbuf->head + NET_SKB_PAD; 4338 skb_reset_tail_pointer(nbuf); 4339 } 4340 qdf_export_symbol(__qdf_nbuf_init); 4341 4342 #ifdef WLAN_FEATURE_FASTPATH 4343 void qdf_nbuf_init_fast(qdf_nbuf_t nbuf) 4344 { 4345 qdf_nbuf_users_set(&nbuf->users, 1); 4346 nbuf->data = nbuf->head + NET_SKB_PAD; 4347 skb_reset_tail_pointer(nbuf); 4348 } 4349 qdf_export_symbol(qdf_nbuf_init_fast); 4350 #endif /* WLAN_FEATURE_FASTPATH */ 4351 4352 4353 #ifdef QDF_NBUF_GLOBAL_COUNT 4354 /** 4355 * __qdf_nbuf_mod_init() - Intialization routine for qdf_nuf 4356 * 4357 * Return void 4358 */ 4359 void __qdf_nbuf_mod_init(void) 4360 { 4361 qdf_atomic_init(&nbuf_count); 4362 qdf_debugfs_create_atomic(NBUF_DEBUGFS_NAME, S_IRUSR, NULL, &nbuf_count); 4363 } 4364 4365 /** 4366 * __qdf_nbuf_mod_exit() - Unintialization routine for qdf_nuf 4367 * 4368 * Return void 4369 */ 4370 void __qdf_nbuf_mod_exit(void) 4371 { 4372 } 4373 #endif 4374