1 /* 2 * Copyright (c) 2017-2018 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: Defines scan utility functions 21 */ 22 23 #include <wlan_cmn.h> 24 #include <wlan_scan_ucfg_api.h> 25 #include <wlan_scan_utils_api.h> 26 #include <../../core/src/wlan_scan_cache_db.h> 27 #include <../../core/src/wlan_scan_main.h> 28 #include <wlan_reg_services_api.h> 29 30 const char* 31 util_scan_get_ev_type_name(enum scan_event_type type) 32 { 33 static const char * const event_name[] = { 34 [SCAN_EVENT_TYPE_STARTED] = "STARTED", 35 [SCAN_EVENT_TYPE_COMPLETED] = "COMPLETED", 36 [SCAN_EVENT_TYPE_BSS_CHANNEL] = "HOME_CHANNEL", 37 [SCAN_EVENT_TYPE_FOREIGN_CHANNEL] = "FOREIGN_CHANNEL", 38 [SCAN_EVENT_TYPE_DEQUEUED] = "DEQUEUED", 39 [SCAN_EVENT_TYPE_PREEMPTED] = "PREEMPTED", 40 [SCAN_EVENT_TYPE_START_FAILED] = "START_FAILED", 41 [SCAN_EVENT_TYPE_RESTARTED] = "RESTARTED", 42 [SCAN_EVENT_TYPE_FOREIGN_CHANNEL_EXIT] = "FOREIGN_CHANNEL_EXIT", 43 [SCAN_EVENT_TYPE_SUSPENDED] = "SUSPENDED", 44 [SCAN_EVENT_TYPE_RESUMED] = "RESUMED", 45 [SCAN_EVENT_TYPE_NLO_COMPLETE] = "NLO_COMPLETE", 46 [SCAN_EVENT_TYPE_NLO_MATCH] = "NLO_MATCH", 47 [SCAN_EVENT_TYPE_INVALID] = "INVALID", 48 [SCAN_EVENT_TYPE_GPIO_TIMEOUT] = "GPIO_TIMEOUT", 49 [SCAN_EVENT_TYPE_RADIO_MEASUREMENT_START] = 50 "RADIO_MEASUREMENT_START", 51 [SCAN_EVENT_TYPE_RADIO_MEASUREMENT_END] = 52 "RADIO_MEASUREMENT_END", 53 [SCAN_EVENT_TYPE_BSSID_MATCH] = "BSSID_MATCH", 54 [SCAN_EVENT_TYPE_FOREIGN_CHANNEL_GET_NF] = 55 "FOREIGN_CHANNEL_GET_NF", 56 }; 57 58 if (type >= SCAN_EVENT_TYPE_MAX) 59 return "UNKNOWN"; 60 61 return event_name[type]; 62 } 63 64 65 const char* 66 util_scan_get_ev_reason_name(enum scan_completion_reason reason) 67 { 68 static const char * const reason_name[] = { 69 [SCAN_REASON_NONE] = "NONE", 70 [SCAN_REASON_COMPLETED] = "COMPLETED", 71 [SCAN_REASON_CANCELLED] = "CANCELLED", 72 [SCAN_REASON_PREEMPTED] = "PREEMPTED", 73 [SCAN_REASON_TIMEDOUT] = "TIMEDOUT", 74 [SCAN_REASON_INTERNAL_FAILURE] = "INTERNAL_FAILURE", 75 [SCAN_REASON_SUSPENDED] = "SUSPENDED", 76 [SCAN_REASON_RUN_FAILED] = "RUN_FAILED", 77 [SCAN_REASON_TERMINATION_FUNCTION] = "TERMINATION_FUNCTION", 78 [SCAN_REASON_MAX_OFFCHAN_RETRIES] = "MAX_OFFCHAN_RETRIES", 79 }; 80 81 if (reason >= SCAN_REASON_MAX) 82 return "UNKNOWN"; 83 84 return reason_name[reason]; 85 } 86 87 qdf_time_t 88 util_get_last_scan_time(struct wlan_objmgr_vdev *vdev) 89 { 90 uint8_t pdev_id; 91 struct wlan_scan_obj *scan_obj; 92 93 if (!vdev) { 94 scm_warn("null vdev"); 95 QDF_ASSERT(0); 96 return 0; 97 } 98 pdev_id = wlan_scan_vdev_get_pdev_id(vdev); 99 scan_obj = wlan_vdev_get_scan_obj(vdev); 100 101 return scan_obj->pdev_info[pdev_id].last_scan_time; 102 } 103 104 enum wlan_band util_scan_scm_chan_to_band(uint32_t chan) 105 { 106 if (WLAN_CHAN_IS_2GHZ(chan)) 107 return WLAN_BAND_2_4_GHZ; 108 109 return WLAN_BAND_5_GHZ; 110 } 111 112 enum wlan_band util_scan_scm_freq_to_band(uint16_t freq) 113 { 114 if (WLAN_REG_IS_24GHZ_CH_FREQ(freq)) 115 return WLAN_BAND_2_4_GHZ; 116 117 return WLAN_BAND_5_GHZ; 118 } 119 120 bool util_is_scan_entry_match( 121 struct scan_cache_entry *entry1, 122 struct scan_cache_entry *entry2) 123 { 124 125 if (entry1->cap_info.wlan_caps.ess != 126 entry2->cap_info.wlan_caps.ess) 127 return false; 128 129 if (entry1->cap_info.wlan_caps.ess && 130 !qdf_mem_cmp(entry1->bssid.bytes, 131 entry2->bssid.bytes, QDF_MAC_ADDR_SIZE) && 132 util_scan_scm_chan_to_band( 133 entry1->channel.chan_idx) == 134 util_scan_scm_chan_to_band(entry2->channel.chan_idx)) { 135 /* Check for BSS */ 136 if (util_is_ssid_match( 137 &entry1->ssid, &entry2->ssid)) 138 return true; 139 } else if (entry1->cap_info.wlan_caps.ibss && 140 (entry1->channel.chan_idx == 141 entry2->channel.chan_idx)) { 142 /* 143 * Same channel cannot have same SSID for 144 * different IBSS, so no need to check BSSID 145 */ 146 if (util_is_ssid_match( 147 &entry1->ssid, &entry2->ssid)) 148 return true; 149 } else if (!entry1->cap_info.wlan_caps.ibss && 150 !entry1->cap_info.wlan_caps.ess && 151 !qdf_mem_cmp(entry1->bssid.bytes, 152 entry2->bssid.bytes, QDF_MAC_ADDR_SIZE)) { 153 /* In case of P2P devices, ess and ibss will be set to zero */ 154 return true; 155 } 156 157 return false; 158 } 159 160 static bool util_is_pureg_rate(uint8_t *rates, uint8_t nrates) 161 { 162 static const uint8_t g_rates[] = {12, 18, 24, 36, 48, 72, 96, 108}; 163 bool pureg = false; 164 uint8_t i, j; 165 166 for (i = 0; i < nrates; i++) { 167 for (j = 0; j < QDF_ARRAY_SIZE(g_rates); j++) { 168 if (WLAN_RV(rates[i]) == g_rates[j]) { 169 pureg = true; 170 break; 171 } 172 } 173 if (pureg) 174 break; 175 } 176 177 return pureg; 178 } 179 static enum wlan_phymode 180 util_scan_get_phymode_5g(struct scan_cache_entry *scan_params) 181 { 182 enum wlan_phymode phymode = WLAN_PHYMODE_AUTO; 183 uint16_t ht_cap = 0; 184 struct htcap_cmn_ie *htcap; 185 struct wlan_ie_htinfo_cmn *htinfo; 186 struct wlan_ie_vhtop *vhtop; 187 188 htcap = (struct htcap_cmn_ie *) 189 util_scan_entry_htcap(scan_params); 190 htinfo = (struct wlan_ie_htinfo_cmn *) 191 util_scan_entry_htinfo(scan_params); 192 vhtop = (struct wlan_ie_vhtop *) 193 util_scan_entry_vhtop(scan_params); 194 195 if (!(htcap && htinfo)) 196 return WLAN_PHYMODE_11A; 197 198 if (htcap) 199 ht_cap = le16toh(htcap->hc_cap); 200 201 if (util_scan_entry_vhtcap(scan_params) && vhtop) { 202 switch (vhtop->vht_op_chwidth) { 203 case WLAN_VHTOP_CHWIDTH_2040: 204 if ((ht_cap & WLAN_HTCAP_C_CHWIDTH40) && 205 (htinfo->hi_extchoff == 206 WLAN_HTINFO_EXTOFFSET_ABOVE)) 207 phymode = WLAN_PHYMODE_11AC_VHT40PLUS; 208 else if ((ht_cap & WLAN_HTCAP_C_CHWIDTH40) && 209 (htinfo->hi_extchoff == 210 WLAN_HTINFO_EXTOFFSET_BELOW)) 211 phymode = WLAN_PHYMODE_11AC_VHT40MINUS; 212 else 213 phymode = WLAN_PHYMODE_11AC_VHT20; 214 break; 215 case WLAN_VHTOP_CHWIDTH_80: 216 if (WLAN_IS_REVSIG_VHT80_80(vhtop)) 217 phymode = WLAN_PHYMODE_11AC_VHT80_80; 218 else if (WLAN_IS_REVSIG_VHT160(vhtop)) 219 phymode = WLAN_PHYMODE_11AC_VHT160; 220 else 221 phymode = WLAN_PHYMODE_11AC_VHT80; 222 break; 223 case WLAN_VHTOP_CHWIDTH_160: 224 phymode = WLAN_PHYMODE_11AC_VHT160; 225 break; 226 case WLAN_VHTOP_CHWIDTH_80_80: 227 phymode = WLAN_PHYMODE_11AC_VHT80_80; 228 break; 229 default: 230 scm_err("bad channel: %d", 231 vhtop->vht_op_chwidth); 232 break; 233 } 234 } else if ((ht_cap & WLAN_HTCAP_C_CHWIDTH40) && 235 (htinfo->hi_extchoff == WLAN_HTINFO_EXTOFFSET_ABOVE)) 236 phymode = WLAN_PHYMODE_11NA_HT40PLUS; 237 else if ((ht_cap & WLAN_HTCAP_C_CHWIDTH40) && 238 (htinfo->hi_extchoff == WLAN_HTINFO_EXTOFFSET_BELOW)) 239 phymode = WLAN_PHYMODE_11NA_HT40MINUS; 240 else 241 phymode = WLAN_PHYMODE_11NA_HT20; 242 243 return phymode; 244 } 245 246 static enum wlan_phymode 247 util_scan_get_phymode_2g(struct scan_cache_entry *scan_params) 248 { 249 enum wlan_phymode phymode = WLAN_PHYMODE_AUTO; 250 uint16_t ht_cap = 0; 251 struct htcap_cmn_ie *htcap; 252 struct wlan_ie_htinfo_cmn *htinfo; 253 struct wlan_ie_vhtop *vhtop; 254 255 htcap = (struct htcap_cmn_ie *) 256 util_scan_entry_htcap(scan_params); 257 htinfo = (struct wlan_ie_htinfo_cmn *) 258 util_scan_entry_htinfo(scan_params); 259 vhtop = (struct wlan_ie_vhtop *) 260 util_scan_entry_vhtop(scan_params); 261 262 if (htcap) 263 ht_cap = le16toh(htcap->hc_cap); 264 265 if (htcap && htinfo) { 266 if ((ht_cap & WLAN_HTCAP_C_CHWIDTH40) && 267 (htinfo->hi_extchoff == WLAN_HTINFO_EXTOFFSET_ABOVE)) 268 phymode = WLAN_PHYMODE_11NG_HT40PLUS; 269 else if ((ht_cap & WLAN_HTCAP_C_CHWIDTH40) && 270 (htinfo->hi_extchoff == WLAN_HTINFO_EXTOFFSET_BELOW)) 271 phymode = WLAN_PHYMODE_11NG_HT40MINUS; 272 else 273 phymode = WLAN_PHYMODE_11NG_HT20; 274 } else if (util_scan_entry_xrates(scan_params)) { 275 /* only 11G stations will have more than 8 rates */ 276 phymode = WLAN_PHYMODE_11G; 277 } else { 278 /* Some mischievous g-only APs do not set extended rates */ 279 if (util_scan_entry_rates(scan_params)) { 280 if (util_is_pureg_rate(&scan_params->ie_list.rates[2], 281 scan_params->ie_list.rates[1])) 282 phymode = WLAN_PHYMODE_11G; 283 else 284 phymode = WLAN_PHYMODE_11B; 285 } else { 286 phymode = WLAN_PHYMODE_11B; 287 } 288 } 289 290 return phymode; 291 } 292 293 static QDF_STATUS 294 util_scan_parse_chan_switch_wrapper_ie(struct scan_cache_entry *scan_params, 295 struct ie_header *sub_ie, qdf_size_t sub_ie_len) 296 { 297 /* Walk through to check nothing is malformed */ 298 while (sub_ie_len >= sizeof(struct ie_header)) { 299 /* At least one more header is present */ 300 sub_ie_len -= sizeof(struct ie_header); 301 302 if (sub_ie->ie_len == 0) { 303 sub_ie += 1; 304 continue; 305 } 306 if (sub_ie_len < sub_ie->ie_len) { 307 scm_err("Incomplete corrupted IE:%x", 308 WLAN_ELEMID_CHAN_SWITCH_WRAP); 309 return QDF_STATUS_E_INVAL; 310 } 311 switch (sub_ie->ie_id) { 312 case WLAN_ELEMID_COUNTRY: 313 scan_params->ie_list.country = (uint8_t *)sub_ie; 314 break; 315 case WLAN_ELEMID_WIDE_BAND_CHAN_SWITCH: 316 scan_params->ie_list.widebw = (uint8_t *)sub_ie; 317 break; 318 case WLAN_ELEMID_VHT_TX_PWR_ENVLP: 319 scan_params->ie_list.txpwrenvlp = (uint8_t *)sub_ie; 320 break; 321 } 322 /* Consume sub info element */ 323 sub_ie_len -= sub_ie->ie_len; 324 /* go to next Sub IE */ 325 sub_ie = (struct ie_header *) 326 (((uint8_t *) sub_ie) + 327 sizeof(struct ie_header) + sub_ie->ie_len); 328 } 329 330 return QDF_STATUS_SUCCESS; 331 } 332 333 bool 334 util_scan_is_hidden_ssid(struct ie_ssid *ssid) 335 { 336 uint8_t i; 337 338 /* 339 * We flag this as Hidden SSID if the Length is 0 340 * of the SSID only contains 0's 341 */ 342 if (!ssid || !ssid->ssid_len) 343 return true; 344 345 for (i = 0; i < ssid->ssid_len; i++) 346 if (ssid->ssid[i] != 0) 347 return false; 348 349 /* All 0's */ 350 return true; 351 } 352 353 static QDF_STATUS 354 util_scan_parse_extn_ie(struct scan_cache_entry *scan_params, 355 struct ie_header *ie) 356 { 357 struct extn_ie_header *extn_ie = (struct extn_ie_header *) ie; 358 359 switch (extn_ie->ie_extn_id) { 360 case WLAN_EXTN_ELEMID_SRP: 361 scan_params->ie_list.srp = (uint8_t *)ie; 362 break; 363 case WLAN_EXTN_ELEMID_HECAP: 364 scan_params->ie_list.hecap = (uint8_t *)ie; 365 break; 366 case WLAN_EXTN_ELEMID_HEOP: 367 scan_params->ie_list.heop = (uint8_t *)ie; 368 break; 369 case WLAN_EXTN_ELEMID_ESP: 370 scan_params->ie_list.esp = (uint8_t *)ie; 371 break; 372 default: 373 break; 374 } 375 return QDF_STATUS_SUCCESS; 376 } 377 378 static QDF_STATUS 379 util_scan_parse_vendor_ie(struct scan_cache_entry *scan_params, 380 struct ie_header *ie) 381 { 382 if (scan_params->ie_list.vendor == NULL) 383 scan_params->ie_list.vendor = (uint8_t *)ie; 384 385 if (is_wpa_oui((uint8_t *)ie)) { 386 scan_params->ie_list.wpa = (uint8_t *)ie; 387 } else if (is_wps_oui((uint8_t *)ie)) { 388 scan_params->ie_list.wps = (uint8_t *)ie; 389 /* WCN IE should be a subset of WPS IE */ 390 if (is_wcn_oui((uint8_t *)ie)) 391 scan_params->ie_list.wcn = (uint8_t *)ie; 392 } else if (is_wme_param((uint8_t *)ie)) { 393 scan_params->ie_list.wmeparam = (uint8_t *)ie; 394 } else if (is_wme_info((uint8_t *)ie)) { 395 scan_params->ie_list.wmeinfo = (uint8_t *)ie; 396 } else if (is_atheros_oui((uint8_t *)ie)) { 397 scan_params->ie_list.athcaps = (uint8_t *)ie; 398 } else if (is_atheros_extcap_oui((uint8_t *)ie)) { 399 scan_params->ie_list.athextcaps = (uint8_t *)ie; 400 } else if (is_sfa_oui((uint8_t *)ie)) { 401 scan_params->ie_list.sfa = (uint8_t *)ie; 402 } else if (is_p2p_oui((uint8_t *)ie)) { 403 scan_params->ie_list.p2p = (uint8_t *)ie; 404 } else if (is_qca_son_oui((uint8_t *)ie, 405 QCA_OUI_WHC_AP_INFO_SUBTYPE)) { 406 scan_params->ie_list.sonadv = (uint8_t *)ie; 407 } else if (is_ht_cap((uint8_t *)ie)) { 408 /* we only care if there isn't already an HT IE (ANA) */ 409 if (scan_params->ie_list.htcap == NULL) { 410 if (ie->ie_len != (WLAN_VENDOR_HT_IE_OFFSET_LEN + 411 sizeof(struct htcap_cmn_ie))) 412 return QDF_STATUS_E_INVAL; 413 scan_params->ie_list.htcap = 414 (uint8_t *)&(((struct wlan_vendor_ie_htcap *)ie)->ie); 415 } 416 } else if (is_ht_info((uint8_t *)ie)) { 417 /* we only care if there isn't already an HT IE (ANA) */ 418 if (scan_params->ie_list.htinfo == NULL) { 419 if (ie->ie_len != WLAN_VENDOR_HT_IE_OFFSET_LEN + 420 sizeof(struct wlan_ie_htinfo_cmn)) 421 return QDF_STATUS_E_INVAL; 422 scan_params->ie_list.htinfo = 423 (uint8_t *)&(((struct wlan_vendor_ie_htinfo *) 424 ie)->hi_ie); 425 } 426 } else if (is_interop_vht((uint8_t *)ie) && 427 !(scan_params->ie_list.vhtop)) { 428 uint8_t *vendor_ie = (uint8_t *)(ie); 429 430 if (ie->ie_len < ((WLAN_VENDOR_VHTCAP_IE_OFFSET + 431 sizeof(struct wlan_ie_vhtcaps)) - 432 sizeof(struct ie_header))) 433 return QDF_STATUS_E_INVAL; 434 vendor_ie = ((uint8_t *)(ie)) + WLAN_VENDOR_VHTCAP_IE_OFFSET; 435 if (vendor_ie[1] != (sizeof(struct wlan_ie_vhtcaps)) - 436 sizeof(struct ie_header)) 437 return QDF_STATUS_E_INVAL; 438 /* location where Interop Vht Cap IE and VHT OP IE Present */ 439 scan_params->ie_list.vhtcap = (((uint8_t *)(ie)) + 440 WLAN_VENDOR_VHTCAP_IE_OFFSET); 441 if (ie->ie_len > ((WLAN_VENDOR_VHTCAP_IE_OFFSET + 442 sizeof(struct wlan_ie_vhtcaps)) - 443 sizeof(struct ie_header)) && 444 ie->ie_len < ((WLAN_VENDOR_VHTOP_IE_OFFSET + 445 sizeof(struct wlan_ie_vhtop)) - 446 sizeof(struct ie_header))) 447 return QDF_STATUS_E_INVAL; 448 vendor_ie = ((uint8_t *)(ie)) + WLAN_VENDOR_VHTOP_IE_OFFSET; 449 if (vendor_ie[1] != (sizeof(struct wlan_ie_vhtop) - 450 sizeof(struct ie_header))) 451 return QDF_STATUS_E_INVAL; 452 scan_params->ie_list.vhtop = (((uint8_t *)(ie)) + 453 WLAN_VENDOR_VHTOP_IE_OFFSET); 454 } else if (is_bwnss_oui((uint8_t *)ie)) { 455 /* 456 * Bandwidth-NSS map has sub-type & version. 457 * hence copy data just after version byte 458 */ 459 scan_params->ie_list.bwnss_map = (((uint8_t *)ie) + 8); 460 } else if (is_mbo_oce_oui((uint8_t *)ie)) { 461 scan_params->ie_list.mbo_oce = (uint8_t *)ie; 462 } 463 return QDF_STATUS_SUCCESS; 464 } 465 466 static QDF_STATUS 467 util_scan_populate_bcn_ie_list(struct scan_cache_entry *scan_params) 468 { 469 struct ie_header *ie, *sub_ie; 470 uint32_t ie_len, sub_ie_len; 471 QDF_STATUS status; 472 473 ie_len = util_scan_entry_ie_len(scan_params); 474 ie = (struct ie_header *) 475 util_scan_entry_ie_data(scan_params); 476 477 while (ie_len >= sizeof(struct ie_header)) { 478 ie_len -= sizeof(struct ie_header); 479 480 if (!ie->ie_len) { 481 ie += 1; 482 continue; 483 } 484 485 if (ie_len < ie->ie_len) { 486 scm_err("Incomplete corrupted IE:%x", 487 ie->ie_id); 488 return QDF_STATUS_E_INVAL; 489 } 490 491 switch (ie->ie_id) { 492 case WLAN_ELEMID_SSID: 493 if (ie->ie_len > (sizeof(struct ie_ssid) - 494 sizeof(struct ie_header))) 495 return QDF_STATUS_E_INVAL; 496 scan_params->ie_list.ssid = (uint8_t *)ie; 497 break; 498 case WLAN_ELEMID_RATES: 499 if (ie->ie_len > WLAN_SUPPORTED_RATES_IE_MAX_LEN) 500 return QDF_STATUS_E_INVAL; 501 scan_params->ie_list.rates = (uint8_t *)ie; 502 break; 503 case WLAN_ELEMID_DSPARMS: 504 if (ie->ie_len != WLAN_DS_PARAM_IE_MAX_LEN) 505 return QDF_STATUS_E_INVAL; 506 scan_params->ie_list.ds_param = (uint8_t *)ie; 507 scan_params->channel.chan_idx = 508 ((struct ds_ie *)ie)->cur_chan; 509 break; 510 case WLAN_ELEMID_TIM: 511 if (ie->ie_len < WLAN_TIM_IE_MIN_LENGTH) 512 return QDF_STATUS_E_INVAL; 513 scan_params->ie_list.tim = (uint8_t *)ie; 514 scan_params->dtim_period = 515 ((struct wlan_tim_ie *)ie)->tim_period; 516 break; 517 case WLAN_ELEMID_COUNTRY: 518 if (ie->ie_len < WLAN_COUNTRY_IE_MIN_LEN) 519 return QDF_STATUS_E_INVAL; 520 scan_params->ie_list.country = (uint8_t *)ie; 521 break; 522 case WLAN_ELEMID_QBSS_LOAD: 523 if (ie->ie_len != sizeof(struct qbss_load_ie) - 524 sizeof(struct ie_header)) 525 return QDF_STATUS_E_INVAL; 526 scan_params->ie_list.qbssload = (uint8_t *)ie; 527 break; 528 case WLAN_ELEMID_CHANSWITCHANN: 529 if (ie->ie_len != WLAN_CSA_IE_MAX_LEN) 530 return QDF_STATUS_E_INVAL; 531 scan_params->ie_list.csa = (uint8_t *)ie; 532 break; 533 case WLAN_ELEMID_IBSSDFS: 534 if (ie->ie_len < WLAN_IBSSDFS_IE_MIN_LEN) 535 return QDF_STATUS_E_INVAL; 536 scan_params->ie_list.ibssdfs = (uint8_t *)ie; 537 break; 538 case WLAN_ELEMID_QUIET: 539 if (ie->ie_len != WLAN_QUIET_IE_MAX_LEN) 540 return QDF_STATUS_E_INVAL; 541 scan_params->ie_list.quiet = (uint8_t *)ie; 542 break; 543 case WLAN_ELEMID_ERP: 544 if (ie->ie_len != (sizeof(struct erp_ie) - 545 sizeof(struct ie_header))) 546 return QDF_STATUS_E_INVAL; 547 scan_params->erp = ((struct erp_ie *)ie)->value; 548 break; 549 case WLAN_ELEMID_HTCAP_ANA: 550 if (ie->ie_len != sizeof(struct htcap_cmn_ie)) 551 return QDF_STATUS_E_INVAL; 552 scan_params->ie_list.htcap = 553 (uint8_t *)&(((struct htcap_ie *)ie)->ie); 554 break; 555 case WLAN_ELEMID_RSN: 556 if (ie->ie_len < WLAN_RSN_IE_MIN_LEN) 557 return QDF_STATUS_E_INVAL; 558 scan_params->ie_list.rsn = (uint8_t *)ie; 559 break; 560 case WLAN_ELEMID_XRATES: 561 scan_params->ie_list.xrates = (uint8_t *)ie; 562 break; 563 case WLAN_ELEMID_EXTCHANSWITCHANN: 564 if (ie->ie_len != WLAN_XCSA_IE_MAX_LEN) 565 return QDF_STATUS_E_INVAL; 566 scan_params->ie_list.xcsa = (uint8_t *)ie; 567 break; 568 case WLAN_ELEMID_SECCHANOFFSET: 569 if (ie->ie_len != WLAN_SECCHANOFF_IE_MAX_LEN) 570 return QDF_STATUS_E_INVAL; 571 scan_params->ie_list.secchanoff = (uint8_t *)ie; 572 break; 573 case WLAN_ELEMID_HTINFO_ANA: 574 if (ie->ie_len != sizeof(struct wlan_ie_htinfo_cmn)) 575 return QDF_STATUS_E_INVAL; 576 scan_params->ie_list.htinfo = 577 (uint8_t *)&(((struct wlan_ie_htinfo *) ie)->hi_ie); 578 scan_params->channel.chan_idx = 579 ((struct wlan_ie_htinfo_cmn *) 580 (scan_params->ie_list.htinfo))->hi_ctrlchannel; 581 break; 582 case WLAN_ELEMID_WAPI: 583 if (ie->ie_len < WLAN_WAPI_IE_MIN_LEN) 584 return QDF_STATUS_E_INVAL; 585 scan_params->ie_list.wapi = (uint8_t *)ie; 586 break; 587 case WLAN_ELEMID_XCAPS: 588 if (ie->ie_len > WLAN_EXTCAP_IE_MAX_LEN) 589 return QDF_STATUS_E_INVAL; 590 scan_params->ie_list.extcaps = (uint8_t *)ie; 591 break; 592 case WLAN_ELEMID_VHTCAP: 593 if (ie->ie_len != (sizeof(struct wlan_ie_vhtcaps) - 594 sizeof(struct ie_header))) 595 return QDF_STATUS_E_INVAL; 596 scan_params->ie_list.vhtcap = (uint8_t *)ie; 597 break; 598 case WLAN_ELEMID_VHTOP: 599 if (ie->ie_len != (sizeof(struct wlan_ie_vhtop) - 600 sizeof(struct ie_header))) 601 return QDF_STATUS_E_INVAL; 602 scan_params->ie_list.vhtop = (uint8_t *)ie; 603 break; 604 case WLAN_ELEMID_OP_MODE_NOTIFY: 605 if (ie->ie_len != WLAN_OPMODE_IE_MAX_LEN) 606 return QDF_STATUS_E_INVAL; 607 scan_params->ie_list.opmode = (uint8_t *)ie; 608 break; 609 case WLAN_ELEMID_MOBILITY_DOMAIN: 610 if (ie->ie_len != WLAN_MOBILITY_DOMAIN_IE_MAX_LEN) 611 return QDF_STATUS_E_INVAL; 612 scan_params->ie_list.mdie = (uint8_t *)ie; 613 break; 614 case WLAN_ELEMID_VENDOR: 615 status = util_scan_parse_vendor_ie(scan_params, 616 ie); 617 if (QDF_IS_STATUS_ERROR(status)) 618 return status; 619 break; 620 case WLAN_ELEMID_CHAN_SWITCH_WRAP: 621 scan_params->ie_list.cswrp = (uint8_t *)ie; 622 /* Go to next sub IE */ 623 sub_ie = (struct ie_header *) 624 (((uint8_t *)ie) + sizeof(struct ie_header)); 625 sub_ie_len = ie->ie_len; 626 status = 627 util_scan_parse_chan_switch_wrapper_ie( 628 scan_params, sub_ie, sub_ie_len); 629 if (QDF_IS_STATUS_ERROR(status)) { 630 scm_err("failed to parse chan_switch_wrapper_ie"); 631 return status; 632 } 633 break; 634 case WLAN_ELEMID_FILS_INDICATION: 635 if (ie->ie_len < WLAN_FILS_INDICATION_IE_MIN_LEN) 636 return QDF_STATUS_E_INVAL; 637 scan_params->ie_list.fils_indication = (uint8_t *)ie; 638 break; 639 case WLAN_ELEMID_EXTN_ELEM: 640 status = util_scan_parse_extn_ie(scan_params, ie); 641 if (QDF_IS_STATUS_ERROR(status)) 642 return status; 643 break; 644 default: 645 break; 646 } 647 648 /* Consume info element */ 649 ie_len -= ie->ie_len; 650 /* Go to next IE */ 651 ie = (struct ie_header *) 652 (((uint8_t *) ie) + 653 sizeof(struct ie_header) + 654 ie->ie_len); 655 } 656 657 return QDF_STATUS_SUCCESS; 658 } 659 660 /** 661 * util_scan_update_esp_data: update ESP params from beacon/probe response 662 * @esp_information: pointer to wlan_esp_information 663 * @scan_entry: new received entry 664 * 665 * The Estimated Service Parameters element is 666 * used by a AP to provide information to another STA which 667 * can then use the information as input to an algorithm to 668 * generate an estimate of throughput between the two STAs. 669 * The ESP Information List field contains from 1 to 4 ESP 670 * Information fields(each field 24 bits), each corresponding 671 * to an access category for which estimated service parameters 672 * information is provided. 673 * 674 * Return: None 675 */ 676 static void util_scan_update_esp_data(struct wlan_esp_ie *esp_information, 677 struct scan_cache_entry *scan_entry) 678 { 679 680 uint8_t *data; 681 int i = 0; 682 uint64_t total_elements; 683 struct wlan_esp_info *esp_info; 684 struct wlan_esp_ie *esp_ie; 685 686 esp_ie = (struct wlan_esp_ie *) 687 util_scan_entry_esp_info(scan_entry); 688 689 total_elements = esp_ie->esp_len; 690 data = (uint8_t *)esp_ie + 3; 691 do_div(total_elements, ESP_INFORMATION_LIST_LENGTH); 692 693 if (total_elements > MAX_ESP_INFORMATION_FIELD) { 694 scm_err("No of Air time fractions are greater than supported"); 695 return; 696 } 697 698 for (i = 0; i < total_elements; i++) { 699 esp_info = (struct wlan_esp_info *)data; 700 if (esp_info->access_category == ESP_AC_BK) { 701 qdf_mem_copy(&esp_information->esp_info_AC_BK, 702 data, 3); 703 data = data + ESP_INFORMATION_LIST_LENGTH; 704 continue; 705 } 706 if (esp_info->access_category == ESP_AC_BE) { 707 qdf_mem_copy(&esp_information->esp_info_AC_BE, 708 data, 3); 709 data = data + ESP_INFORMATION_LIST_LENGTH; 710 continue; 711 } 712 if (esp_info->access_category == ESP_AC_VI) { 713 qdf_mem_copy(&esp_information->esp_info_AC_VI, 714 data, 3); 715 data = data + ESP_INFORMATION_LIST_LENGTH; 716 continue; 717 } 718 if (esp_info->access_category == ESP_AC_VO) { 719 qdf_mem_copy(&esp_information->esp_info_AC_VO, 720 data, 3); 721 data = data + ESP_INFORMATION_LIST_LENGTH; 722 break; 723 } 724 } 725 } 726 727 /** 728 * util_scan_scm_update_bss_with_esp_dataa: calculate estimated air time 729 * fraction 730 * @scan_entry: new received entry 731 * 732 * This function process all Access category ESP params and provide 733 * best effort air time fraction. 734 * If best effort is not available, it will choose VI, VO and BK in sequence 735 * 736 */ 737 static void util_scan_scm_update_bss_with_esp_data( 738 struct scan_cache_entry *scan_entry) 739 { 740 uint8_t air_time_fraction = 0; 741 struct wlan_esp_ie esp_information; 742 743 if (!scan_entry->ie_list.esp) 744 return; 745 746 util_scan_update_esp_data(&esp_information, scan_entry); 747 748 /* 749 * If the ESP metric is transmitting multiple airtime fractions, then 750 * follow the sequence AC_BE, AC_VI, AC_VO, AC_BK and pick whichever is 751 * the first one available 752 */ 753 if (esp_information.esp_info_AC_BE.access_category 754 == ESP_AC_BE) 755 air_time_fraction = 756 esp_information.esp_info_AC_BE. 757 estimated_air_fraction; 758 else if (esp_information.esp_info_AC_VI.access_category 759 == ESP_AC_VI) 760 air_time_fraction = 761 esp_information.esp_info_AC_VI. 762 estimated_air_fraction; 763 else if (esp_information.esp_info_AC_VO.access_category 764 == ESP_AC_VO) 765 air_time_fraction = 766 esp_information.esp_info_AC_VO. 767 estimated_air_fraction; 768 else if (esp_information.esp_info_AC_BK.access_category 769 == ESP_AC_BK) 770 air_time_fraction = 771 esp_information.esp_info_AC_BK. 772 estimated_air_fraction; 773 scan_entry->air_time_fraction = air_time_fraction; 774 } 775 776 /** 777 * util_scan_scm_calc_nss_supported_by_ap() - finds out nss from AP 778 * @scan_entry: new received entry 779 * 780 * Return: number of nss advertised by AP 781 */ 782 static int util_scan_scm_calc_nss_supported_by_ap( 783 struct scan_cache_entry *scan_params) 784 { 785 struct htcap_cmn_ie *htcap; 786 struct wlan_ie_vhtcaps *vhtcaps; 787 uint8_t rx_mcs_map; 788 789 htcap = (struct htcap_cmn_ie *) 790 util_scan_entry_htcap(scan_params); 791 vhtcaps = (struct wlan_ie_vhtcaps *) 792 util_scan_entry_vhtcap(scan_params); 793 if (vhtcaps) { 794 rx_mcs_map = vhtcaps->rx_mcs_map; 795 if ((rx_mcs_map & 0xC0) != 0xC0) 796 return 4; 797 798 if ((rx_mcs_map & 0x30) != 0x30) 799 return 3; 800 801 if ((rx_mcs_map & 0x0C) != 0x0C) 802 return 2; 803 } else if (htcap) { 804 if (htcap->mcsset[3]) 805 return 4; 806 807 if (htcap->mcsset[2]) 808 return 3; 809 810 if (htcap->mcsset[1]) 811 return 2; 812 813 } 814 return 1; 815 } 816 817 qdf_list_t * 818 util_scan_unpack_beacon_frame(struct wlan_objmgr_pdev *pdev, uint8_t *frame, 819 qdf_size_t frame_len, uint32_t frm_subtype, 820 struct mgmt_rx_event_params *rx_param) 821 { 822 struct wlan_frame_hdr *hdr; 823 struct wlan_bcn_frame *bcn; 824 QDF_STATUS status; 825 struct ie_ssid *ssid; 826 struct scan_cache_entry *scan_entry; 827 struct qbss_load_ie *qbss_load; 828 qdf_list_t *scan_list; 829 struct scan_cache_node *scan_node; 830 831 scan_list = qdf_mem_malloc(sizeof(*scan_list)); 832 if (!scan_list) { 833 scm_err("failed to allocate scan_list"); 834 return NULL; 835 } 836 qdf_list_create(scan_list, MAX_SCAN_CACHE_SIZE); 837 838 scan_entry = qdf_mem_malloc(sizeof(*scan_entry)); 839 if (!scan_entry) { 840 scm_err("failed to allocate memory for scan_entry"); 841 qdf_mem_free(scan_list); 842 return NULL; 843 } 844 scan_entry->raw_frame.ptr = 845 qdf_mem_malloc(frame_len); 846 if (!scan_entry->raw_frame.ptr) { 847 scm_err("failed to allocate memory for frame"); 848 qdf_mem_free(scan_entry); 849 qdf_mem_free(scan_list); 850 return NULL; 851 } 852 853 bcn = (struct wlan_bcn_frame *) 854 (frame + sizeof(*hdr)); 855 hdr = (struct wlan_frame_hdr *)frame; 856 857 /* update timestamp in nanoseconds needed by kernel layers */ 858 scan_entry->boottime_ns = qdf_get_bootbased_boottime_ns(); 859 860 scan_entry->frm_subtype = frm_subtype; 861 qdf_mem_copy(scan_entry->bssid.bytes, 862 hdr->i_addr3, QDF_MAC_ADDR_SIZE); 863 /* Scr addr */ 864 qdf_mem_copy(scan_entry->mac_addr.bytes, 865 hdr->i_addr2, QDF_MAC_ADDR_SIZE); 866 scan_entry->seq_num = 867 (le16toh(*(uint16_t *)hdr->i_seq) >> WLAN_SEQ_SEQ_SHIFT); 868 869 scan_entry->rssi_raw = rx_param->rssi; 870 scan_entry->avg_rssi = WLAN_RSSI_IN(scan_entry->rssi_raw); 871 scan_entry->tsf_delta = rx_param->tsf_delta; 872 873 /* Copy per chain rssi to scan entry */ 874 qdf_mem_copy(scan_entry->per_chain_snr, rx_param->rssi_ctl, 875 WLAN_MGMT_TXRX_HOST_MAX_ANTENNA); 876 877 /* store jiffies */ 878 scan_entry->rrm_parent_tsf = (u_int32_t) qdf_system_ticks(); 879 880 scan_entry->bcn_int = le16toh(bcn->beacon_interval); 881 882 /* 883 * In case if the beacon dosnt have 884 * valid beacon interval falback to def 885 */ 886 if (!scan_entry->bcn_int) 887 scan_entry->bcn_int = 100; 888 scan_entry->cap_info.value = le16toh(bcn->capability.value); 889 qdf_mem_copy(scan_entry->tsf_info.data, 890 bcn->timestamp, 8); 891 scan_entry->erp = ERP_NON_ERP_PRESENT; 892 893 scan_entry->scan_entry_time = 894 qdf_mc_timer_get_system_time(); 895 896 scan_entry->raw_frame.len = frame_len; 897 qdf_mem_copy(scan_entry->raw_frame.ptr, 898 frame, frame_len); 899 status = util_scan_populate_bcn_ie_list(scan_entry); 900 if (QDF_IS_STATUS_ERROR(status)) { 901 scm_err("failed to parse beacon IE"); 902 qdf_mem_free(scan_entry->raw_frame.ptr); 903 qdf_mem_free(scan_entry); 904 qdf_mem_free(scan_list); 905 return NULL; 906 } 907 908 if (!scan_entry->ie_list.rates) { 909 qdf_mem_free(scan_entry->raw_frame.ptr); 910 qdf_mem_free(scan_entry); 911 qdf_mem_free(scan_list); 912 return NULL; 913 } 914 915 ssid = (struct ie_ssid *) 916 scan_entry->ie_list.ssid; 917 918 if (ssid && (ssid->ssid_len > WLAN_SSID_MAX_LEN)) { 919 qdf_mem_free(scan_entry->raw_frame.ptr); 920 qdf_mem_free(scan_entry); 921 qdf_mem_free(scan_list); 922 return NULL; 923 } 924 925 if (scan_entry->ie_list.p2p) 926 scan_entry->is_p2p = true; 927 928 /* If no channel info is present in beacon use meta channel */ 929 if (!scan_entry->channel.chan_idx) { 930 scan_entry->channel.chan_idx = 931 rx_param->channel; 932 } else if (rx_param->channel != 933 scan_entry->channel.chan_idx) { 934 if (!wlan_reg_chan_is_49ghz(pdev, scan_entry->channel.chan_idx)) 935 scan_entry->channel_mismatch = true; 936 } 937 938 if (util_scan_is_hidden_ssid(ssid)) { 939 scan_entry->ie_list.ssid = NULL; 940 } else { 941 qdf_mem_copy(scan_entry->ssid.ssid, 942 ssid->ssid, WLAN_SSID_MAX_LEN); 943 scan_entry->ssid.length = ssid->ssid_len; 944 scan_entry->hidden_ssid_timestamp = 945 scan_entry->scan_entry_time; 946 } 947 948 if (WLAN_CHAN_IS_5GHZ(scan_entry->channel.chan_idx)) 949 scan_entry->phy_mode = util_scan_get_phymode_5g(scan_entry); 950 else 951 scan_entry->phy_mode = util_scan_get_phymode_2g(scan_entry); 952 953 scan_entry->nss = util_scan_scm_calc_nss_supported_by_ap(scan_entry); 954 util_scan_scm_update_bss_with_esp_data(scan_entry); 955 qbss_load = (struct qbss_load_ie *) 956 util_scan_entry_qbssload(scan_entry); 957 if (qbss_load) 958 scan_entry->qbss_chan_load = qbss_load->qbss_chan_load; 959 960 scan_node = qdf_mem_malloc(sizeof(*scan_node)); 961 if (!scan_node) { 962 qdf_mem_free(scan_entry->raw_frame.ptr); 963 qdf_mem_free(scan_entry); 964 qdf_mem_free(scan_list); 965 return NULL; 966 } 967 968 scan_node->entry = scan_entry; 969 qdf_list_insert_front(scan_list, &scan_node->node); 970 971 /* TODO calculate channel struct */ 972 return scan_list; 973 } 974 975 QDF_STATUS 976 util_scan_entry_update_mlme_info(struct wlan_objmgr_pdev *pdev, 977 struct scan_cache_entry *scan_entry) 978 { 979 980 if (!pdev || !scan_entry) { 981 scm_err("pdev 0x%pK, scan_entry: 0x%pK", pdev, scan_entry); 982 return QDF_STATUS_E_INVAL; 983 } 984 985 return scm_update_scan_mlme_info(pdev, scan_entry); 986 } 987