// SPDX-License-Identifier: GPL-2.0 /* Copyright(c) 2007 - 2012 Realtek Corporation. */ #define _RTW_RECV_C_ #include #include "../include/osdep_service.h" #include "../include/drv_types.h" #include "../include/recv_osdep.h" #include "../include/mlme_osdep.h" #include "../include/usb_ops.h" #include "../include/wifi.h" #include "../include/rtl8188e_recv.h" #include static u8 SNAP_ETH_TYPE_IPX[2] = {0x81, 0x37}; static u8 SNAP_ETH_TYPE_APPLETALK_AARP[2] = {0x80, 0xf3}; /* Bridge-Tunnel header (for EtherTypes ETH_P_AARP and ETH_P_IPX) */ static u8 rtw_bridge_tunnel_header[] = { 0xaa, 0xaa, 0x03, 0x00, 0x00, 0xf8 }; static u8 rtw_rfc1042_header[] = { 0xaa, 0xaa, 0x03, 0x00, 0x00, 0x00 }; #if LINUX_VERSION_CODE >= KERNEL_VERSION(4, 15, 0) void rtw_signal_stat_timer_hdl(struct timer_list *); #else void rtw_signal_stat_timer_hdl(RTW_TIMER_HDL_ARGS); #endif void _rtw_init_sta_recv_priv(struct sta_recv_priv *psta_recvpriv) { memset((u8 *)psta_recvpriv, 0, sizeof(struct sta_recv_priv)); spin_lock_init(&psta_recvpriv->lock); rtw_init_queue(&psta_recvpriv->defrag_q); } int _rtw_init_recv_priv(struct recv_priv *precvpriv, struct adapter *padapter) { int i; struct recv_frame *precvframe; int res = _SUCCESS; spin_lock_init(&precvpriv->lock); rtw_init_queue(&precvpriv->free_recv_queue); rtw_init_queue(&precvpriv->recv_pending_queue); rtw_init_queue(&precvpriv->uc_swdec_pending_queue); precvpriv->adapter = padapter; precvpriv->free_recvframe_cnt = NR_RECVFRAME; precvpriv->pallocated_frame_buf = vzalloc(NR_RECVFRAME * sizeof(struct recv_frame) + RXFRAME_ALIGN_SZ); if (!precvpriv->pallocated_frame_buf) { res = _FAIL; goto exit; } precvpriv->precv_frame_buf = (u8 *)N_BYTE_ALIGMENT((size_t)(precvpriv->pallocated_frame_buf), RXFRAME_ALIGN_SZ); precvframe = (struct recv_frame *)precvpriv->precv_frame_buf; for (i = 0; i < NR_RECVFRAME; i++) { INIT_LIST_HEAD(&precvframe->list); list_add_tail(&precvframe->list, &precvpriv->free_recv_queue.queue); precvframe->pkt_newalloc = NULL; precvframe->pkt = NULL; precvframe->len = 0; precvframe->adapter = padapter; precvframe++; } precvpriv->rx_pending_cnt = 1; sema_init(&precvpriv->allrxreturnevt, 0); res = rtl8188eu_init_recv_priv(padapter); #if LINUX_VERSION_CODE >= KERNEL_VERSION(4, 15, 0) timer_setup(&precvpriv->signal_stat_timer, rtw_signal_stat_timer_hdl, 0); #else _init_timer(&precvpriv->signal_stat_timer, padapter->pnetdev, RTW_TIMER_HDL_NAME(signal_stat), padapter); #endif precvpriv->signal_stat_sampling_interval = 1000; /* ms */ rtw_set_signal_stat_timer(precvpriv); exit: return res; } void _rtw_free_recv_priv(struct recv_priv *precvpriv) { struct adapter *padapter = precvpriv->adapter; rtw_free_uc_swdec_pending_queue(padapter); vfree(precvpriv->pallocated_frame_buf); rtl8188eu_free_recv_priv(padapter); _cancel_timer_ex(&precvpriv->signal_stat_timer); } struct recv_frame *_rtw_alloc_recvframe(struct __queue *pfree_recv_queue) { struct recv_frame *hdr; struct list_head *plist, *phead; struct adapter *padapter; struct recv_priv *precvpriv; if (list_empty(&pfree_recv_queue->queue)) { hdr = NULL; } else { phead = get_list_head(pfree_recv_queue); plist = phead->next; hdr = container_of(plist, struct recv_frame, list); list_del_init(&hdr->list); padapter = hdr->adapter; if (padapter) { precvpriv = &padapter->recvpriv; if (pfree_recv_queue == &precvpriv->free_recv_queue) precvpriv->free_recvframe_cnt--; } } return (struct recv_frame *)hdr; } struct recv_frame *rtw_alloc_recvframe(struct __queue *pfree_recv_queue) { struct recv_frame *precvframe; spin_lock_bh(&pfree_recv_queue->lock); precvframe = _rtw_alloc_recvframe(pfree_recv_queue); spin_unlock_bh(&pfree_recv_queue->lock); return precvframe; } int rtw_free_recvframe(struct recv_frame *precvframe, struct __queue *pfree_recv_queue) { struct adapter *padapter; struct recv_priv *precvpriv; if (!precvframe) return _FAIL; padapter = precvframe->adapter; precvpriv = &padapter->recvpriv; if (precvframe->pkt) { dev_kfree_skb_any(precvframe->pkt);/* free skb by driver */ precvframe->pkt = NULL; } spin_lock_bh(&pfree_recv_queue->lock); list_del_init(&precvframe->list); precvframe->len = 0; list_add_tail(&precvframe->list, get_list_head(pfree_recv_queue)); if (padapter) { if (pfree_recv_queue == &precvpriv->free_recv_queue) precvpriv->free_recvframe_cnt++; } spin_unlock_bh(&pfree_recv_queue->lock); return _SUCCESS; } int _rtw_enqueue_recvframe(struct recv_frame *precvframe, struct __queue *queue) { struct adapter *padapter = precvframe->adapter; struct recv_priv *precvpriv = &padapter->recvpriv; list_del_init(&precvframe->list); list_add_tail(&precvframe->list, get_list_head(queue)); if (padapter) { if (queue == &precvpriv->free_recv_queue) precvpriv->free_recvframe_cnt++; } return _SUCCESS; } int rtw_enqueue_recvframe(struct recv_frame *precvframe, struct __queue *queue) { int ret; spin_lock_bh(&queue->lock); ret = _rtw_enqueue_recvframe(precvframe, queue); spin_unlock_bh(&queue->lock); return ret; } /* caller : defrag ; recvframe_chk_defrag in recv_thread (passive) pframequeue: defrag_queue : will be accessed in recv_thread (passive) using spinlock to protect */ void rtw_free_recvframe_queue(struct __queue *pframequeue, struct __queue *pfree_recv_queue) { struct recv_frame *hdr; struct list_head *plist, *phead; spin_lock(&pframequeue->lock); phead = get_list_head(pframequeue); plist = phead->next; while (phead != plist) { hdr = container_of(plist, struct recv_frame, list); plist = plist->next; rtw_free_recvframe((struct recv_frame *)hdr, pfree_recv_queue); } spin_unlock(&pframequeue->lock); } u32 rtw_free_uc_swdec_pending_queue(struct adapter *adapter) { u32 cnt = 0; struct recv_frame *pending_frame; while ((pending_frame = rtw_alloc_recvframe(&adapter->recvpriv.uc_swdec_pending_queue))) { rtw_free_recvframe(pending_frame, &adapter->recvpriv.free_recv_queue); cnt++; } return cnt; } static int recvframe_chkmic(struct adapter *adapter, struct recv_frame *precvframe) { int i, res = _SUCCESS; u32 datalen; u8 miccode[8]; u8 bmic_err = false, brpt_micerror = true; u8 *pframe, *payload, *pframemic; u8 *mickey; struct sta_info *stainfo; struct rx_pkt_attrib *prxattrib = &precvframe->attrib; struct security_priv *psecuritypriv = &adapter->securitypriv; struct mlme_ext_priv *pmlmeext = &adapter->mlmeextpriv; struct mlme_ext_info *pmlmeinfo = &pmlmeext->mlmext_info; stainfo = rtw_get_stainfo(&adapter->stapriv, &prxattrib->ta[0]); if (prxattrib->encrypt == _TKIP_) { /* calculate mic code */ if (stainfo) { if (is_multicast_ether_addr(prxattrib->ra)) { mickey = &psecuritypriv->dot118021XGrprxmickey[prxattrib->key_index].skey[0]; if (!psecuritypriv) { res = _FAIL; goto exit; } } else { mickey = &stainfo->dot11tkiprxmickey.skey[0]; } datalen = precvframe->len - prxattrib->hdrlen - prxattrib->iv_len - prxattrib->icv_len - 8;/* icv_len included the mic code */ pframe = precvframe->rx_data; payload = pframe + prxattrib->hdrlen + prxattrib->iv_len; rtw_seccalctkipmic(mickey, pframe, payload, datalen, &miccode[0], (unsigned char)prxattrib->priority); /* care the length of the data */ pframemic = payload + datalen; bmic_err = false; for (i = 0; i < 8; i++) { if (miccode[i] != *(pframemic + i)) bmic_err = true; } if (bmic_err) { /* double check key_index for some timing issue , */ /* cannot compare with psecuritypriv->dot118021XGrpKeyid also cause timing issue */ if (is_multicast_ether_addr(prxattrib->ra) && prxattrib->key_index != pmlmeinfo->key_index) brpt_micerror = false; if ((prxattrib->bdecrypted) && (brpt_micerror)) rtw_handle_tkip_mic_err(adapter, (u8)is_multicast_ether_addr(prxattrib->ra)); res = _FAIL; } else { /* mic checked ok */ if (!psecuritypriv->bcheck_grpkey && is_multicast_ether_addr(prxattrib->ra)) psecuritypriv->bcheck_grpkey = true; } } recvframe_pull_tail(precvframe, 8); } exit: return res; } /* decrypt and set the ivlen, icvlen of the recv_frame */ static struct recv_frame *decryptor(struct adapter *padapter, struct recv_frame *precv_frame) { struct rx_pkt_attrib *prxattrib = &precv_frame->attrib; struct security_priv *psecuritypriv = &padapter->securitypriv; struct recv_frame *return_packet = precv_frame; u32 res = _SUCCESS; if (prxattrib->encrypt > 0) { u8 *iv = precv_frame->rx_data + prxattrib->hdrlen; prxattrib->key_index = (((iv[3]) >> 6) & 0x3); if (prxattrib->key_index > WEP_KEYS) { switch (prxattrib->encrypt) { case _WEP40_: case _WEP104_: prxattrib->key_index = psecuritypriv->dot11PrivacyKeyIndex; break; case _TKIP_: case _AES_: default: prxattrib->key_index = psecuritypriv->dot118021XGrpKeyid; break; } } } if ((prxattrib->encrypt > 0) && ((prxattrib->bdecrypted == 0) || (psecuritypriv->sw_decrypt))) { psecuritypriv->hw_decrypted = false; switch (prxattrib->encrypt) { case _WEP40_: case _WEP104_: rtw_wep_decrypt(padapter, precv_frame); break; case _TKIP_: res = rtw_tkip_decrypt(padapter, precv_frame); break; case _AES_: res = rtw_aes_decrypt(padapter, precv_frame); break; default: break; } } else if (prxattrib->bdecrypted == 1 && prxattrib->encrypt > 0 && (psecuritypriv->busetkipkey == 1 || prxattrib->encrypt != _TKIP_)) psecuritypriv->hw_decrypted = true; if (res == _FAIL) { rtw_free_recvframe(return_packet, &padapter->recvpriv.free_recv_queue); return_packet = NULL; } else { prxattrib->bdecrypted = true; } return return_packet; } /* set the security information in the recv_frame */ static struct recv_frame *portctrl(struct adapter *adapter, struct recv_frame *precv_frame) { u8 *psta_addr, *ptr; uint auth_alg; struct recv_frame *pfhdr; struct sta_info *psta; struct sta_priv *pstapriv; struct recv_frame *prtnframe; u16 ether_type = 0; u16 eapol_type = 0x888e;/* for Funia BD's WPA issue */ struct rx_pkt_attrib *pattrib; __be16 be_tmp; pstapriv = &adapter->stapriv; auth_alg = adapter->securitypriv.dot11AuthAlgrthm; ptr = precv_frame->rx_data; pfhdr = precv_frame; pattrib = &pfhdr->attrib; psta_addr = pattrib->ta; prtnframe = NULL; psta = rtw_get_stainfo(pstapriv, psta_addr); if (auth_alg == 2) { if (psta && psta->ieee8021x_blocked) { /* blocked */ /* only accept EAPOL frame */ prtnframe = precv_frame; /* get ether_type */ ptr = ptr + pfhdr->attrib.hdrlen + pfhdr->attrib.iv_len + LLC_HEADER_SIZE; memcpy(&be_tmp, ptr, 2); ether_type = ntohs(be_tmp); if (ether_type == eapol_type) { prtnframe = precv_frame; } else { /* free this frame */ rtw_free_recvframe(precv_frame, &adapter->recvpriv.free_recv_queue); prtnframe = NULL; } } else { /* allowed */ /* check decryption status, and decrypt the frame if needed */ prtnframe = precv_frame; } } else { prtnframe = precv_frame; } return prtnframe; } static int recv_decache(struct recv_frame *precv_frame, u8 bretry, struct stainfo_rxcache *prxcache) { int tid = precv_frame->attrib.priority; u16 seq_ctrl = ((precv_frame->attrib.seq_num & 0xffff) << 4) | (precv_frame->attrib.frag_num & 0xf); if (tid > 15) return _FAIL; if (1) {/* if (bretry) */ if (seq_ctrl == prxcache->tid_rxseq[tid]) return _FAIL; } prxcache->tid_rxseq[tid] = seq_ctrl; return _SUCCESS; } void process_pwrbit_data(struct adapter *padapter, struct recv_frame *precv_frame); void process_pwrbit_data(struct adapter *padapter, struct recv_frame *precv_frame) { unsigned char pwrbit; u8 *ptr = precv_frame->rx_data; struct rx_pkt_attrib *pattrib = &precv_frame->attrib; struct sta_priv *pstapriv = &padapter->stapriv; struct sta_info *psta = NULL; psta = rtw_get_stainfo(pstapriv, pattrib->src); pwrbit = GetPwrMgt(ptr); if (psta) { if (pwrbit) { if (!(psta->state & WIFI_SLEEP_STATE)) stop_sta_xmit(padapter, psta); } else { if (psta->state & WIFI_SLEEP_STATE) wakeup_sta_to_xmit(padapter, psta); } } } static void process_wmmps_data(struct adapter *padapter, struct recv_frame *precv_frame) { struct rx_pkt_attrib *pattrib = &precv_frame->attrib; struct sta_priv *pstapriv = &padapter->stapriv; struct sta_info *psta = NULL; psta = rtw_get_stainfo(pstapriv, pattrib->src); if (!psta) return; if (!psta->qos_option) return; if (!(psta->qos_info & 0xf)) return; if (psta->state & WIFI_SLEEP_STATE) { u8 wmmps_ac = 0; switch (pattrib->priority) { case 1: case 2: wmmps_ac = psta->uapsd_bk & BIT(1); break; case 4: case 5: wmmps_ac = psta->uapsd_vi & BIT(1); break; case 6: case 7: wmmps_ac = psta->uapsd_vo & BIT(1); break; case 0: case 3: default: wmmps_ac = psta->uapsd_be & BIT(1); break; } if (wmmps_ac) { if (psta->sleepq_ac_len > 0) { /* process received triggered frame */ xmit_delivery_enabled_frames(padapter, psta); } else { /* issue one qos null frame with More data bit = 0 and the EOSP bit set (= 1) */ issue_qos_nulldata(padapter, psta->hwaddr, (u16)pattrib->priority, 0, 0); } } } } static void count_rx_stats(struct adapter *padapter, struct recv_frame *prframe, struct sta_info *sta) { int sz; struct sta_info *psta = NULL; struct stainfo_stats *pstats = NULL; struct rx_pkt_attrib *pattrib = &prframe->attrib; struct recv_priv *precvpriv = &padapter->recvpriv; sz = get_recvframe_len(prframe); precvpriv->rx_bytes += sz; padapter->mlmepriv.LinkDetectInfo.NumRxOkInPeriod++; if (!is_broadcast_ether_addr(pattrib->dst) && !is_multicast_ether_addr(pattrib->dst)) padapter->mlmepriv.LinkDetectInfo.NumRxUnicastOkInPeriod++; if (sta) psta = sta; else psta = prframe->psta; if (psta) { pstats = &psta->sta_stats; pstats->rx_data_pkts++; pstats->rx_bytes += sz; } } int sta2sta_data_frame( struct adapter *adapter, struct recv_frame *precv_frame, struct sta_info **psta ); int sta2sta_data_frame(struct adapter *adapter, struct recv_frame *precv_frame, struct sta_info **psta) { u8 *ptr = precv_frame->rx_data; int ret = _SUCCESS; struct rx_pkt_attrib *pattrib = &precv_frame->attrib; struct sta_priv *pstapriv = &adapter->stapriv; struct mlme_priv *pmlmepriv = &adapter->mlmepriv; u8 *mybssid = get_bssid(pmlmepriv); u8 *myhwaddr = myid(&adapter->eeprompriv); u8 *sta_addr = NULL; bool bmcast = is_multicast_ether_addr(pattrib->dst); if (check_fwstate(pmlmepriv, WIFI_ADHOC_STATE) || check_fwstate(pmlmepriv, WIFI_ADHOC_MASTER_STATE)) { /* filter packets that SA is myself or multicast or broadcast */ if (!memcmp(myhwaddr, pattrib->src, ETH_ALEN)) { ret = _FAIL; goto exit; } if ((memcmp(myhwaddr, pattrib->dst, ETH_ALEN)) && (!bmcast)) { ret = _FAIL; goto exit; } if (!memcmp(pattrib->bssid, "\x0\x0\x0\x0\x0\x0", ETH_ALEN) || !memcmp(mybssid, "\x0\x0\x0\x0\x0\x0", ETH_ALEN) || memcmp(pattrib->bssid, mybssid, ETH_ALEN)) { ret = _FAIL; goto exit; } sta_addr = pattrib->src; } else if (check_fwstate(pmlmepriv, WIFI_STATION_STATE)) { /* For Station mode, sa and bssid should always be BSSID, and DA is my mac-address */ if (memcmp(pattrib->bssid, pattrib->src, ETH_ALEN)) { ret = _FAIL; goto exit; } sta_addr = pattrib->bssid; } else if (check_fwstate(pmlmepriv, WIFI_AP_STATE)) { if (bmcast) { /* For AP mode, if DA == MCAST, then BSSID should be also MCAST */ if (!is_multicast_ether_addr(pattrib->bssid)) { ret = _FAIL; goto exit; } } else { /* not mc-frame */ /* For AP mode, if DA is non-MCAST, then it must be BSSID, and bssid == BSSID */ if (memcmp(pattrib->bssid, pattrib->dst, ETH_ALEN)) { ret = _FAIL; goto exit; } sta_addr = pattrib->src; } } else if (check_fwstate(pmlmepriv, WIFI_MP_STATE)) { memcpy(pattrib->dst, GetAddr1Ptr(ptr), ETH_ALEN); memcpy(pattrib->src, GetAddr2Ptr(ptr), ETH_ALEN); memcpy(pattrib->bssid, GetAddr3Ptr(ptr), ETH_ALEN); memcpy(pattrib->ra, pattrib->dst, ETH_ALEN); memcpy(pattrib->ta, pattrib->src, ETH_ALEN); sta_addr = mybssid; } else { ret = _FAIL; } if (bmcast) *psta = rtw_get_bcmc_stainfo(adapter); else *psta = rtw_get_stainfo(pstapriv, sta_addr); /* get ap_info */ if (!*psta) goto exit; exit: return ret; } static int ap2sta_data_frame( struct adapter *adapter, struct recv_frame *precv_frame, struct sta_info **psta) { u8 *ptr = precv_frame->rx_data; struct rx_pkt_attrib *pattrib = &precv_frame->attrib; int ret = _SUCCESS; struct sta_priv *pstapriv = &adapter->stapriv; struct mlme_priv *pmlmepriv = &adapter->mlmepriv; u8 *mybssid = get_bssid(pmlmepriv); u8 *myhwaddr = myid(&adapter->eeprompriv); bool bmcast = is_multicast_ether_addr(pattrib->dst); if (check_fwstate(pmlmepriv, WIFI_STATION_STATE) && (check_fwstate(pmlmepriv, _FW_LINKED) || check_fwstate(pmlmepriv, _FW_UNDER_LINKING))) { /* filter packets that SA is myself or multicast or broadcast */ if (!memcmp(myhwaddr, pattrib->src, ETH_ALEN)) { ret = _FAIL; goto exit; } /* da should be for me */ if ((memcmp(myhwaddr, pattrib->dst, ETH_ALEN)) && (!bmcast)) { ret = _FAIL; goto exit; } /* check BSSID */ if (!memcmp(pattrib->bssid, "\x0\x0\x0\x0\x0\x0", ETH_ALEN) || !memcmp(mybssid, "\x0\x0\x0\x0\x0\x0", ETH_ALEN) || (memcmp(pattrib->bssid, mybssid, ETH_ALEN))) { if (!bmcast) issue_deauth(adapter, pattrib->bssid, WLAN_REASON_CLASS3_FRAME_FROM_NONASSOC_STA); ret = _FAIL; goto exit; } if (bmcast) *psta = rtw_get_bcmc_stainfo(adapter); else *psta = rtw_get_stainfo(pstapriv, pattrib->bssid); /* get ap_info */ if (!*psta) { ret = _FAIL; goto exit; } /* if ((GetFrameSubType(ptr) & WIFI_QOS_DATA_TYPE) == WIFI_QOS_DATA_TYPE) { */ /* */ if (GetFrameSubType(ptr) & BIT(6)) { /* No data, will not indicate to upper layer, temporily count it here */ count_rx_stats(adapter, precv_frame, *psta); ret = RTW_RX_HANDLED; goto exit; } } else if (check_fwstate(pmlmepriv, WIFI_MP_STATE) && check_fwstate(pmlmepriv, _FW_LINKED)) { memcpy(pattrib->dst, GetAddr1Ptr(ptr), ETH_ALEN); memcpy(pattrib->src, GetAddr2Ptr(ptr), ETH_ALEN); memcpy(pattrib->bssid, GetAddr3Ptr(ptr), ETH_ALEN); memcpy(pattrib->ra, pattrib->dst, ETH_ALEN); memcpy(pattrib->ta, pattrib->src, ETH_ALEN); /* */ memcpy(pattrib->bssid, mybssid, ETH_ALEN); *psta = rtw_get_stainfo(pstapriv, pattrib->bssid); /* get sta_info */ if (!*psta) { ret = _FAIL; goto exit; } } else if (check_fwstate(pmlmepriv, WIFI_AP_STATE)) { /* Special case */ ret = RTW_RX_HANDLED; goto exit; } else { if (!memcmp(myhwaddr, pattrib->dst, ETH_ALEN) && (!bmcast)) { *psta = rtw_get_stainfo(pstapriv, pattrib->bssid); /* get sta_info */ if (!*psta) issue_deauth(adapter, pattrib->bssid, WLAN_REASON_CLASS3_FRAME_FROM_NONASSOC_STA); } ret = _FAIL; } exit: return ret; } static int sta2ap_data_frame(struct adapter *adapter, struct recv_frame *precv_frame, struct sta_info **psta) { struct rx_pkt_attrib *pattrib = &precv_frame->attrib; struct sta_priv *pstapriv = &adapter->stapriv; struct mlme_priv *pmlmepriv = &adapter->mlmepriv; u8 *ptr = precv_frame->rx_data; unsigned char *mybssid = get_bssid(pmlmepriv); int ret = _SUCCESS; if (check_fwstate(pmlmepriv, WIFI_AP_STATE)) { /* For AP mode, RA = BSSID, TX = STA(SRC_ADDR), A3 = DST_ADDR */ if (memcmp(pattrib->bssid, mybssid, ETH_ALEN)) { ret = _FAIL; goto exit; } *psta = rtw_get_stainfo(pstapriv, pattrib->src); if (!*psta) { issue_deauth(adapter, pattrib->src, WLAN_REASON_CLASS3_FRAME_FROM_NONASSOC_STA); ret = RTW_RX_HANDLED; goto exit; } process_pwrbit_data(adapter, precv_frame); if ((GetFrameSubType(ptr) & WIFI_QOS_DATA_TYPE) == WIFI_QOS_DATA_TYPE) { process_wmmps_data(adapter, precv_frame); } if (GetFrameSubType(ptr) & BIT(6)) { /* No data, will not indicate to upper layer, temporily count it here */ count_rx_stats(adapter, precv_frame, *psta); ret = RTW_RX_HANDLED; goto exit; } } else { u8 *myhwaddr = myid(&adapter->eeprompriv); if (memcmp(pattrib->ra, myhwaddr, ETH_ALEN)) { ret = RTW_RX_HANDLED; goto exit; } issue_deauth(adapter, pattrib->src, WLAN_REASON_CLASS3_FRAME_FROM_NONASSOC_STA); ret = RTW_RX_HANDLED; goto exit; } exit: return ret; } static int validate_recv_ctrl_frame(struct adapter *padapter, struct recv_frame *precv_frame) { struct rx_pkt_attrib *pattrib = &precv_frame->attrib; struct sta_priv *pstapriv = &padapter->stapriv; u8 *pframe = precv_frame->rx_data; /* uint len = precv_frame->len; */ if (GetFrameType(pframe) != WIFI_CTRL_TYPE) return _FAIL; /* receive the frames that ra(a1) is my address */ if (memcmp(GetAddr1Ptr(pframe), myid(&padapter->eeprompriv), ETH_ALEN)) return _FAIL; /* only handle ps-poll */ if (GetFrameSubType(pframe) == WIFI_PSPOLL) { u16 aid; u8 wmmps_ac = 0; struct sta_info *psta = NULL; aid = GetAid(pframe); psta = rtw_get_stainfo(pstapriv, GetAddr2Ptr(pframe)); if (!psta || psta->aid != aid) return _FAIL; /* for rx pkt statistics */ psta->sta_stats.rx_ctrl_pkts++; switch (pattrib->priority) { case 1: case 2: wmmps_ac = psta->uapsd_bk & BIT(0); break; case 4: case 5: wmmps_ac = psta->uapsd_vi & BIT(0); break; case 6: case 7: wmmps_ac = psta->uapsd_vo & BIT(0); break; case 0: case 3: default: wmmps_ac = psta->uapsd_be & BIT(0); break; } if (wmmps_ac) return _FAIL; if (psta->state & WIFI_STA_ALIVE_CHK_STATE) { psta->expire_to = pstapriv->expire_to; psta->state ^= WIFI_STA_ALIVE_CHK_STATE; } if ((psta->state & WIFI_SLEEP_STATE) && (pstapriv->sta_dz_bitmap & BIT(psta->aid))) { struct list_head *xmitframe_plist, *xmitframe_phead; struct xmit_frame *pxmitframe = NULL; struct xmit_priv *pxmitpriv = &padapter->xmitpriv; spin_lock_bh(&pxmitpriv->lock); xmitframe_phead = get_list_head(&psta->sleep_q); xmitframe_plist = xmitframe_phead->next; if (xmitframe_phead != xmitframe_plist) { pxmitframe = container_of(xmitframe_plist, struct xmit_frame, list); xmitframe_plist = xmitframe_plist->next; list_del_init(&pxmitframe->list); psta->sleepq_len--; if (psta->sleepq_len > 0) pxmitframe->attrib.mdata = 1; else pxmitframe->attrib.mdata = 0; pxmitframe->attrib.triggered = 1; if (psta->sleepq_len == 0) { pstapriv->tim_bitmap &= ~BIT(psta->aid); /* upate BCN for TIM IE */ /* update_BCNTIM(padapter); */ update_beacon(padapter, _TIM_IE_, NULL, false); } } else { if (pstapriv->tim_bitmap & BIT(psta->aid)) { if (psta->sleepq_len == 0) /* issue nulldata with More data bit = 0 to indicate we have no buffered packets */ issue_nulldata(padapter, psta->hwaddr, 0, 0, 0); else psta->sleepq_len = 0; pstapriv->tim_bitmap &= ~BIT(psta->aid); /* upate BCN for TIM IE */ /* update_BCNTIM(padapter); */ update_beacon(padapter, _TIM_IE_, NULL, false); } } spin_unlock_bh(&pxmitpriv->lock); } } return _FAIL; } struct recv_frame *recvframe_chk_defrag(struct adapter *padapter, struct recv_frame *precv_frame); static int validate_recv_mgnt_frame(struct adapter *padapter, struct recv_frame *precv_frame) { struct sta_info *psta; precv_frame = recvframe_chk_defrag(padapter, precv_frame); if (!precv_frame) return _SUCCESS; /* for rx pkt statistics */ psta = rtw_get_stainfo(&padapter->stapriv, GetAddr2Ptr(precv_frame->rx_data)); if (psta) { psta->sta_stats.rx_mgnt_pkts++; if (GetFrameSubType(precv_frame->rx_data) == WIFI_BEACON) { psta->sta_stats.rx_beacon_pkts++; } else if (GetFrameSubType(precv_frame->rx_data) == WIFI_PROBEREQ) { psta->sta_stats.rx_probereq_pkts++; } else if (GetFrameSubType(precv_frame->rx_data) == WIFI_PROBERSP) { if (!memcmp(padapter->eeprompriv.mac_addr, GetAddr1Ptr(precv_frame->rx_data), ETH_ALEN)) psta->sta_stats.rx_probersp_pkts++; else if (is_broadcast_mac_addr(GetAddr1Ptr(precv_frame->rx_data)) || is_multicast_mac_addr(GetAddr1Ptr(precv_frame->rx_data))) psta->sta_stats.rx_probersp_bm_pkts++; else psta->sta_stats.rx_probersp_uo_pkts++; } } mgt_dispatcher(padapter, precv_frame); return _SUCCESS; } static int validate_recv_data_frame(struct adapter *adapter, struct recv_frame *precv_frame) { u8 bretry; u8 *psa, *pda, *pbssid; struct sta_info *psta = NULL; u8 *ptr = precv_frame->rx_data; struct rx_pkt_attrib *pattrib = &precv_frame->attrib; struct security_priv *psecuritypriv = &adapter->securitypriv; int ret = _SUCCESS; bretry = GetRetry(ptr); pda = get_da(ptr); psa = get_sa(ptr); pbssid = get_hdr_bssid(ptr); if (!pbssid) { ret = _FAIL; goto exit; } memcpy(pattrib->dst, pda, ETH_ALEN); memcpy(pattrib->src, psa, ETH_ALEN); memcpy(pattrib->bssid, pbssid, ETH_ALEN); switch (pattrib->to_fr_ds) { case 0: memcpy(pattrib->ra, pda, ETH_ALEN); memcpy(pattrib->ta, psa, ETH_ALEN); ret = sta2sta_data_frame(adapter, precv_frame, &psta); break; case 1: memcpy(pattrib->ra, pda, ETH_ALEN); memcpy(pattrib->ta, pbssid, ETH_ALEN); ret = ap2sta_data_frame(adapter, precv_frame, &psta); break; case 2: memcpy(pattrib->ra, pbssid, ETH_ALEN); memcpy(pattrib->ta, psa, ETH_ALEN); ret = sta2ap_data_frame(adapter, precv_frame, &psta); break; case 3: memcpy(pattrib->ra, GetAddr1Ptr(ptr), ETH_ALEN); memcpy(pattrib->ta, GetAddr2Ptr(ptr), ETH_ALEN); ret = _FAIL; break; default: ret = _FAIL; break; } if (ret == _FAIL) { goto exit; } else if (ret == RTW_RX_HANDLED) { goto exit; } if (!psta) { ret = _FAIL; goto exit; } /* psta->rssi = prxcmd->rssi; */ /* psta->signal_quality = prxcmd->sq; */ precv_frame->psta = psta; pattrib->amsdu = 0; pattrib->ack_policy = 0; /* parsing QC field */ if (pattrib->qos) { pattrib->priority = GetPriority((ptr + 24)); pattrib->ack_policy = GetAckpolicy((ptr + 24)); pattrib->amsdu = GetAMsdu((ptr + 24)); pattrib->hdrlen = pattrib->to_fr_ds == 3 ? 32 : 26; if (pattrib->priority != 0 && pattrib->priority != 3) adapter->recvpriv.bIsAnyNonBEPkts = true; } else { pattrib->priority = 0; pattrib->hdrlen = pattrib->to_fr_ds == 3 ? 30 : 24; } if (pattrib->order)/* HT-CTRL 11n */ pattrib->hdrlen += 4; precv_frame->preorder_ctrl = &psta->recvreorder_ctrl[pattrib->priority]; /* decache, drop duplicate recv packets */ if (recv_decache(precv_frame, bretry, &psta->sta_recvpriv.rxcache) == _FAIL) { ret = _FAIL; goto exit; } if (pattrib->privacy) { GET_ENCRY_ALGO(psecuritypriv, psta, pattrib->encrypt, is_multicast_ether_addr(pattrib->ra)); SET_ICE_IV_LEN(pattrib->iv_len, pattrib->icv_len, pattrib->encrypt); } else { pattrib->encrypt = 0; pattrib->iv_len = 0; pattrib->icv_len = 0; } exit: return ret; } static int validate_recv_frame(struct adapter *adapter, struct recv_frame *precv_frame) { /* shall check frame subtype, to / from ds, da, bssid */ /* then call check if rx seq/frag. duplicated. */ int retval = _FAIL; u8 bDumpRxPkt; struct rx_pkt_attrib *pattrib = &precv_frame->attrib; u8 *ptr = precv_frame->rx_data; __le16 fc = *(__le16 *)ptr; u8 ver = (unsigned char)(*ptr) & 0x3; struct mlme_ext_priv *pmlmeext = &adapter->mlmeextpriv; if (pmlmeext->sitesurvey_res.state == SCAN_PROCESS) { int ch_set_idx = rtw_ch_set_search_ch(pmlmeext->channel_set, rtw_get_oper_ch(adapter)); if (ch_set_idx >= 0) pmlmeext->channel_set[ch_set_idx].rx_count++; } /* add version chk */ if (ver != 0) return _FAIL; pattrib->to_fr_ds = get_tofr_ds(ptr); pattrib->frag_num = GetFragNum(ptr); pattrib->seq_num = GetSequence(ptr); pattrib->pw_save = GetPwrMgt(ptr); pattrib->mfrag = ieee80211_has_morefrags(fc); pattrib->mdata = ieee80211_has_moredata(fc); pattrib->privacy = ieee80211_has_protected(fc); pattrib->order = ieee80211_has_order(fc); /* Dump rx packets */ GetHalDefVar8188EUsb(adapter, HAL_DEF_DBG_DUMP_RXPKT, &bDumpRxPkt); /* We return _SUCCESS only for data frames. */ if (ieee80211_is_mgmt(fc)) validate_recv_mgnt_frame(adapter, precv_frame); else if (ieee80211_is_ctl(fc)) validate_recv_ctrl_frame(adapter, precv_frame); else if (ieee80211_is_data(fc)) { rtw_led_control(adapter, LED_CTL_RX); pattrib->qos = ieee80211_is_data_qos(fc); retval = validate_recv_data_frame(adapter, precv_frame); if (retval == _FAIL) { struct recv_priv *precvpriv = &adapter->recvpriv; precvpriv->rx_drop++; } } return retval; } /* remove the wlanhdr and add the eth_hdr */ static int wlanhdr_to_ethhdr(struct recv_frame *precvframe) { int rmv_len; u16 eth_type, len; __be16 be_tmp; u8 bsnaphdr; u8 *psnap_type; struct ieee80211_snap_hdr *psnap; int ret = _SUCCESS; struct adapter *adapter = precvframe->adapter; struct mlme_priv *pmlmepriv = &adapter->mlmepriv; u8 *ptr = precvframe->rx_data; /* point to frame_ctrl field */ struct rx_pkt_attrib *pattrib = &precvframe->attrib; if (pattrib->encrypt) recvframe_pull_tail(precvframe, pattrib->icv_len); psnap = (struct ieee80211_snap_hdr *)(ptr + pattrib->hdrlen + pattrib->iv_len); psnap_type = ptr + pattrib->hdrlen + pattrib->iv_len + SNAP_SIZE; /* convert hdr + possible LLC headers into Ethernet header */ if ((!memcmp(psnap, rtw_rfc1042_header, SNAP_SIZE) && memcmp(psnap_type, SNAP_ETH_TYPE_IPX, 2) && memcmp(psnap_type, SNAP_ETH_TYPE_APPLETALK_AARP, 2)) || !memcmp(psnap, rtw_bridge_tunnel_header, SNAP_SIZE)) { /* remove RFC1042 or Bridge-Tunnel encapsulation and replace EtherType */ bsnaphdr = true; } else { /* Leave Ethernet header part of hdr and full payload */ bsnaphdr = false; } rmv_len = pattrib->hdrlen + pattrib->iv_len + (bsnaphdr ? SNAP_SIZE : 0); len = precvframe->len - rmv_len; memcpy(&be_tmp, ptr + rmv_len, 2); eth_type = ntohs(be_tmp); /* pattrib->ether_type */ pattrib->eth_type = eth_type; if ((check_fwstate(pmlmepriv, WIFI_MP_STATE))) { ptr += rmv_len; *ptr = 0x87; *(ptr + 1) = 0x12; eth_type = 0x8712; /* append rx status for mp test packets */ ptr = recvframe_pull(precvframe, (rmv_len - sizeof(struct ethhdr) + 2) - 24); if (!ptr) return _FAIL; memcpy(ptr, get_rxmem(precvframe), 24); ptr += 24; } else { ptr = recvframe_pull(precvframe, (rmv_len - sizeof(struct ethhdr) + (bsnaphdr ? 2 : 0))); if (!ptr) return _FAIL; } memcpy(ptr, pattrib->dst, ETH_ALEN); memcpy(ptr + ETH_ALEN, pattrib->src, ETH_ALEN); if (!bsnaphdr) { be_tmp = htons(len); memcpy(ptr + 12, &be_tmp, 2); } return ret; } /* perform defrag */ static struct recv_frame *recvframe_defrag(struct adapter *adapter, struct __queue *defrag_q) { struct list_head *plist, *phead; u8 wlanhdr_offset; u8 curfragnum; struct recv_frame *pfhdr, *pnfhdr; struct recv_frame *prframe, *pnextrframe; struct __queue *pfree_recv_queue; curfragnum = 0; pfree_recv_queue = &adapter->recvpriv.free_recv_queue; phead = get_list_head(defrag_q); plist = phead->next; pfhdr = container_of(plist, struct recv_frame, list); prframe = (struct recv_frame *)pfhdr; list_del_init(&prframe->list); if (curfragnum != pfhdr->attrib.frag_num) { /* the first fragment number must be 0 */ /* free the whole queue */ rtw_free_recvframe(prframe, pfree_recv_queue); rtw_free_recvframe_queue(defrag_q, pfree_recv_queue); return NULL; } curfragnum++; plist = get_list_head(defrag_q); plist = phead->next; pfhdr = container_of(plist, struct recv_frame, list); prframe = (struct recv_frame *)pfhdr; list_del_init(&prframe->list); plist = plist->next; while (phead != plist) { pnfhdr = container_of(plist, struct recv_frame, list); pnextrframe = (struct recv_frame *)pnfhdr; /* check the fragment sequence (2nd ~n fragment frame) */ if (curfragnum != pnfhdr->attrib.frag_num) { /* the fragment number must be increasing (after decache) */ /* release the defrag_q & prframe */ rtw_free_recvframe(prframe, pfree_recv_queue); rtw_free_recvframe_queue(defrag_q, pfree_recv_queue); return NULL; } curfragnum++; /* copy the 2nd~n fragment frame's payload to the first fragment */ /* get the 2nd~last fragment frame's payload */ wlanhdr_offset = pnfhdr->attrib.hdrlen + pnfhdr->attrib.iv_len; recvframe_pull(pnextrframe, wlanhdr_offset); /* append to first fragment frame's tail (if privacy frame, pull the ICV) */ recvframe_pull_tail(prframe, pfhdr->attrib.icv_len); /* memcpy */ memcpy(pfhdr->rx_tail, pnfhdr->rx_data, pnfhdr->len); recvframe_put(prframe, pnfhdr->len); pfhdr->attrib.icv_len = pnfhdr->attrib.icv_len; plist = plist->next; } /* free the defrag_q queue and return the prframe */ rtw_free_recvframe_queue(defrag_q, pfree_recv_queue); return prframe; } /* check if need to defrag, if needed queue the frame to defrag_q */ struct recv_frame *recvframe_chk_defrag(struct adapter *padapter, struct recv_frame *precv_frame) { u8 ismfrag; u8 fragnum; u8 *psta_addr; struct recv_frame *pfhdr; struct sta_info *psta; struct sta_priv *pstapriv; struct list_head *phead; struct recv_frame *prtnframe = NULL; struct __queue *pfree_recv_queue, *pdefrag_q; pstapriv = &padapter->stapriv; pfhdr = precv_frame; pfree_recv_queue = &padapter->recvpriv.free_recv_queue; /* need to define struct of wlan header frame ctrl */ ismfrag = pfhdr->attrib.mfrag; fragnum = pfhdr->attrib.frag_num; psta_addr = pfhdr->attrib.ta; psta = rtw_get_stainfo(pstapriv, psta_addr); if (!psta) { u8 type = GetFrameType(pfhdr->rx_data); if (type != WIFI_DATA_TYPE) { psta = rtw_get_bcmc_stainfo(padapter); pdefrag_q = &psta->sta_recvpriv.defrag_q; } else { pdefrag_q = NULL; } } else { pdefrag_q = &psta->sta_recvpriv.defrag_q; } if ((ismfrag == 0) && (fragnum == 0)) prtnframe = precv_frame;/* isn't a fragment frame */ if (ismfrag == 1) { /* 0~(n-1) fragment frame */ /* enqueue to defraf_g */ if (pdefrag_q) { if (fragnum == 0) { /* the first fragment */ if (!list_empty(&pdefrag_q->queue)) { /* free current defrag_q */ rtw_free_recvframe_queue(pdefrag_q, pfree_recv_queue); } } /* Then enqueue the 0~(n-1) fragment into the defrag_q */ phead = get_list_head(pdefrag_q); list_add_tail(&pfhdr->list, phead); prtnframe = NULL; } else { /* can't find this ta's defrag_queue, so free this recv_frame */ if (precv_frame && pfree_recv_queue) rtw_free_recvframe(precv_frame, pfree_recv_queue); prtnframe = NULL; } } if ((ismfrag == 0) && (fragnum != 0)) { /* the last fragment frame */ /* enqueue the last fragment */ if (pdefrag_q) { phead = get_list_head(pdefrag_q); list_add_tail(&pfhdr->list, phead); /* call recvframe_defrag to defrag */ precv_frame = recvframe_defrag(padapter, pdefrag_q); prtnframe = precv_frame; } else { /* can't find this ta's defrag_queue, so free this recv_frame */ if (precv_frame && pfree_recv_queue) rtw_free_recvframe(precv_frame, pfree_recv_queue); prtnframe = NULL; } } if (prtnframe && prtnframe->attrib.privacy) { /* after defrag we must check tkip mic code */ if (recvframe_chkmic(padapter, prtnframe) == _FAIL) { if (precv_frame && pfree_recv_queue) rtw_free_recvframe(prtnframe, pfree_recv_queue); prtnframe = NULL; } } return prtnframe; } static int amsdu_to_msdu(struct adapter *padapter, struct recv_frame *prframe) { int a_len, padding_len; u16 eth_type, nSubframe_Length; u8 nr_subframes, i; unsigned char *pdata; struct rx_pkt_attrib *pattrib; unsigned char *data_ptr; struct sk_buff *sub_skb, *subframes[MAX_SUBFRAME_COUNT]; struct recv_priv *precvpriv = &padapter->recvpriv; struct __queue *pfree_recv_queue = &precvpriv->free_recv_queue; int ret = _SUCCESS; nr_subframes = 0; pattrib = &prframe->attrib; recvframe_pull(prframe, prframe->attrib.hdrlen); if (prframe->attrib.iv_len > 0) recvframe_pull(prframe, prframe->attrib.iv_len); a_len = prframe->len; pdata = prframe->rx_data; while (a_len > ETH_HLEN) { /* Offset 12 denote 2 mac address */ nSubframe_Length = RTW_GET_BE16(pdata + 12); if (a_len < ETH_HLEN + nSubframe_Length) goto exit; /* move the data point to data content */ pdata += ETH_HLEN; a_len -= ETH_HLEN; /* Allocate new skb for releasing to upper layer */ sub_skb = dev_alloc_skb(nSubframe_Length + 12); if (sub_skb) { skb_reserve(sub_skb, 12); data_ptr = (u8 *)skb_put(sub_skb, nSubframe_Length); memcpy(data_ptr, pdata, nSubframe_Length); } else { sub_skb = skb_clone(prframe->pkt, GFP_ATOMIC); if (sub_skb) { sub_skb->data = pdata; sub_skb->len = nSubframe_Length; skb_set_tail_pointer(sub_skb, nSubframe_Length); } else { break; } } subframes[nr_subframes++] = sub_skb; if (nr_subframes >= MAX_SUBFRAME_COUNT) break; pdata += nSubframe_Length; a_len -= nSubframe_Length; if (a_len != 0) { padding_len = 4 - ((nSubframe_Length + ETH_HLEN) & (4 - 1)); if (padding_len == 4) { padding_len = 0; } if (a_len < padding_len) { goto exit; } pdata += padding_len; a_len -= padding_len; } } for (i = 0; i < nr_subframes; i++) { sub_skb = subframes[i]; /* convert hdr + possible LLC headers into Ethernet header */ eth_type = RTW_GET_BE16(&sub_skb->data[6]); if (sub_skb->len >= 8 && ((!memcmp(sub_skb->data, rtw_rfc1042_header, SNAP_SIZE) && eth_type != ETH_P_AARP && eth_type != ETH_P_IPX) || !memcmp(sub_skb->data, rtw_bridge_tunnel_header, SNAP_SIZE))) { /* remove RFC1042 or Bridge-Tunnel encapsulation and replace EtherType */ skb_pull(sub_skb, SNAP_SIZE); memcpy(skb_push(sub_skb, ETH_ALEN), pattrib->src, ETH_ALEN); memcpy(skb_push(sub_skb, ETH_ALEN), pattrib->dst, ETH_ALEN); } else { __be16 len; /* Leave Ethernet header part of hdr and full payload */ len = htons(sub_skb->len); memcpy(skb_push(sub_skb, 2), &len, 2); memcpy(skb_push(sub_skb, ETH_ALEN), pattrib->src, ETH_ALEN); memcpy(skb_push(sub_skb, ETH_ALEN), pattrib->dst, ETH_ALEN); } /* Indicate the packets to upper layer */ /* Insert NAT2.5 RX here! */ sub_skb->protocol = eth_type_trans(sub_skb, padapter->pnetdev); sub_skb->dev = padapter->pnetdev; sub_skb->ip_summed = CHECKSUM_NONE; netif_rx(sub_skb); } exit: prframe->len = 0; rtw_free_recvframe(prframe, pfree_recv_queue);/* free this recv_frame */ return ret; } static bool check_indicate_seq(struct recv_reorder_ctrl *preorder_ctrl, u16 seq_num) { u8 wsize = preorder_ctrl->wsize_b; u16 wend = (preorder_ctrl->indicate_seq + wsize - 1) & 0xFFF;/* 4096; */ /* Rx Reorder initialize condition. */ if (preorder_ctrl->indicate_seq == 0xFFFF) preorder_ctrl->indicate_seq = seq_num; /* Drop out the packet which SeqNum is smaller than WinStart */ if (SN_LESS(seq_num, preorder_ctrl->indicate_seq)) return false; /* */ /* Sliding window manipulation. Conditions includes: */ /* 1. Incoming SeqNum is equal to WinStart =>Window shift 1 */ /* 2. Incoming SeqNum is larger than the WinEnd => Window shift N */ /* */ if (SN_EQUAL(seq_num, preorder_ctrl->indicate_seq)) { preorder_ctrl->indicate_seq = (preorder_ctrl->indicate_seq + 1) & 0xFFF; } else if (SN_LESS(wend, seq_num)) { if (seq_num >= (wsize - 1)) preorder_ctrl->indicate_seq = seq_num + 1 - wsize; else preorder_ctrl->indicate_seq = 0xFFF - (wsize - (seq_num + 1)) + 1; } return true; } static bool enqueue_reorder_recvframe(struct recv_reorder_ctrl *preorder_ctrl, struct recv_frame *prframe) { struct rx_pkt_attrib *pattrib = &prframe->attrib; struct __queue *ppending_recvframe_queue = &preorder_ctrl->pending_recvframe_queue; struct list_head *phead, *plist; struct recv_frame *hdr; struct rx_pkt_attrib *pnextattrib; phead = get_list_head(ppending_recvframe_queue); plist = phead->next; while (phead != plist) { hdr = container_of(plist, struct recv_frame, list); pnextattrib = &hdr->attrib; if (SN_LESS(pnextattrib->seq_num, pattrib->seq_num)) plist = plist->next; else if (SN_EQUAL(pnextattrib->seq_num, pattrib->seq_num)) return false; else break; } list_del_init(&prframe->list); list_add_tail(&prframe->list, plist); return true; } static bool recv_indicatepkts_in_order(struct adapter *padapter, struct recv_reorder_ctrl *preorder_ctrl, int bforced) { struct list_head *phead, *plist; struct recv_frame *prframe; struct rx_pkt_attrib *pattrib; int bPktInBuf = false; struct recv_priv *precvpriv = &padapter->recvpriv; struct __queue *ppending_recvframe_queue = &preorder_ctrl->pending_recvframe_queue; phead = get_list_head(ppending_recvframe_queue); plist = phead->next; /* Handling some condition for forced indicate case. */ if (bforced) { if (list_empty(phead)) return true; prframe = container_of(plist, struct recv_frame, list); pattrib = &prframe->attrib; preorder_ctrl->indicate_seq = pattrib->seq_num; } /* Prepare indication list and indication. */ /* Check if there is any packet need indicate. */ while (!list_empty(phead)) { prframe = container_of(plist, struct recv_frame, list); pattrib = &prframe->attrib; if (!SN_LESS(preorder_ctrl->indicate_seq, pattrib->seq_num)) { plist = plist->next; list_del_init(&prframe->list); if (SN_EQUAL(preorder_ctrl->indicate_seq, pattrib->seq_num)) preorder_ctrl->indicate_seq = (preorder_ctrl->indicate_seq + 1) & 0xFFF; /* Set this as a lock to make sure that only one thread is indicating packet. */ /* indicate this recv_frame */ if (!pattrib->amsdu) { if ((!padapter->bDriverStopped) && (!padapter->bSurpriseRemoved)) rtw_recv_indicatepkt(padapter, prframe);/* indicate this recv_frame */ } else if (pattrib->amsdu == 1) { if (amsdu_to_msdu(padapter, prframe) != _SUCCESS) rtw_free_recvframe(prframe, &precvpriv->free_recv_queue); } else { /* error condition; */ } /* Update local variables. */ bPktInBuf = false; } else { bPktInBuf = true; break; } } return bPktInBuf; } static int recv_indicatepkt_reorder(struct adapter *padapter, struct recv_frame *prframe) { int retval = _SUCCESS; struct rx_pkt_attrib *pattrib = &prframe->attrib; struct recv_reorder_ctrl *preorder_ctrl = prframe->preorder_ctrl; struct __queue *ppending_recvframe_queue = &preorder_ctrl->pending_recvframe_queue; if (!pattrib->amsdu) { /* s1. */ wlanhdr_to_ethhdr(prframe); if (!pattrib->qos) { if (!padapter->bDriverStopped && !padapter->bSurpriseRemoved) { rtw_recv_indicatepkt(padapter, prframe); return _SUCCESS; } return _FAIL; } if (!preorder_ctrl->enable) { /* indicate this recv_frame */ preorder_ctrl->indicate_seq = pattrib->seq_num; rtw_recv_indicatepkt(padapter, prframe); preorder_ctrl->indicate_seq = (preorder_ctrl->indicate_seq + 1) % 4096; return _SUCCESS; } } else if (pattrib->amsdu == 1) { /* temp filter -> means didn't support A-MSDUs in a A-MPDU */ if (!preorder_ctrl->enable) { preorder_ctrl->indicate_seq = pattrib->seq_num; retval = amsdu_to_msdu(padapter, prframe); preorder_ctrl->indicate_seq = (preorder_ctrl->indicate_seq + 1) % 4096; return retval; } } spin_lock_bh(&ppending_recvframe_queue->lock); /* s2. check if winstart_b(indicate_seq) needs to been updated */ if (!check_indicate_seq(preorder_ctrl, pattrib->seq_num)) goto _err_exit; /* s3. Insert all packet into Reorder Queue to maintain its ordering. */ if (!enqueue_reorder_recvframe(preorder_ctrl, prframe)) goto _err_exit; /* s4. */ /* Indication process. */ /* After Packet dropping and Sliding Window shifting as above, we can now just indicate the packets */ /* with the SeqNum smaller than latest WinStart and buffer other packets. */ /* */ /* For Rx Reorder condition: */ /* 1. All packets with SeqNum smaller than WinStart => Indicate */ /* 2. All packets with SeqNum larger than or equal to WinStart => Buffer it. */ /* */ /* recv_indicatepkts_in_order(padapter, preorder_ctrl, true); */ if (recv_indicatepkts_in_order(padapter, preorder_ctrl, false)) { _set_timer(&preorder_ctrl->reordering_ctrl_timer, REORDER_WAIT_TIME); spin_unlock_bh(&ppending_recvframe_queue->lock); } else { spin_unlock_bh(&ppending_recvframe_queue->lock); _cancel_timer_ex(&preorder_ctrl->reordering_ctrl_timer); } return _SUCCESS; _err_exit: spin_unlock_bh(&ppending_recvframe_queue->lock); return _FAIL; } void rtw_reordering_ctrl_timeout_handler(void *pcontext) { struct recv_reorder_ctrl *preorder_ctrl = (struct recv_reorder_ctrl *)pcontext; struct adapter *padapter = preorder_ctrl->padapter; struct __queue *ppending_recvframe_queue = &preorder_ctrl->pending_recvframe_queue; if (padapter->bDriverStopped || padapter->bSurpriseRemoved) return; spin_lock_bh(&ppending_recvframe_queue->lock); if (recv_indicatepkts_in_order(padapter, preorder_ctrl, true)) _set_timer(&preorder_ctrl->reordering_ctrl_timer, REORDER_WAIT_TIME); spin_unlock_bh(&ppending_recvframe_queue->lock); } static int process_recv_indicatepkts(struct adapter *padapter, struct recv_frame *prframe) { int retval = _SUCCESS; /* struct recv_priv *precvpriv = &padapter->recvpriv; */ /* struct rx_pkt_attrib *pattrib = &prframe->attrib; */ struct mlme_priv *pmlmepriv = &padapter->mlmepriv; struct ht_priv *phtpriv = &pmlmepriv->htpriv; if (phtpriv->ht_option) { /* B/G/N Mode */ /* prframe->preorder_ctrl = &precvpriv->recvreorder_ctrl[pattrib->priority]; */ if (recv_indicatepkt_reorder(padapter, prframe) != _SUCCESS) { /* including perform A-MPDU Rx Ordering Buffer Control */ if ((!padapter->bDriverStopped) && (!padapter->bSurpriseRemoved)) { retval = _FAIL; return retval; } } } else { /* B/G mode */ retval = wlanhdr_to_ethhdr(prframe); if (retval != _SUCCESS) return retval; if ((!padapter->bDriverStopped) && (!padapter->bSurpriseRemoved)) { /* indicate this recv_frame */ rtw_recv_indicatepkt(padapter, prframe); } else { retval = _FAIL; return retval; } } return retval; } static int recv_func_prehandle(struct adapter *padapter, struct recv_frame *rframe) { int ret = _SUCCESS; struct __queue *pfree_recv_queue = &padapter->recvpriv.free_recv_queue; /* check the frame crtl field and decache */ ret = validate_recv_frame(padapter, rframe); if (ret != _SUCCESS) { rtw_free_recvframe(rframe, pfree_recv_queue);/* free this recv_frame */ goto exit; } exit: return ret; } static int recv_func_posthandle(struct adapter *padapter, struct recv_frame *prframe) { int ret = _SUCCESS; struct recv_frame *orig_prframe = prframe; struct recv_priv *precvpriv = &padapter->recvpriv; struct __queue *pfree_recv_queue = &padapter->recvpriv.free_recv_queue; /* DATA FRAME */ rtw_led_control(padapter, LED_CTL_RX); prframe = decryptor(padapter, prframe); if (!prframe) { ret = _FAIL; goto _recv_data_drop; } prframe = recvframe_chk_defrag(padapter, prframe); if (!prframe) goto _recv_data_drop; prframe = portctrl(padapter, prframe); if (!prframe) { ret = _FAIL; goto _recv_data_drop; } count_rx_stats(padapter, prframe, NULL); ret = process_recv_indicatepkts(padapter, prframe); if (ret != _SUCCESS) { rtw_free_recvframe(orig_prframe, pfree_recv_queue);/* free this recv_frame */ goto _recv_data_drop; } return ret; _recv_data_drop: precvpriv->rx_drop++; return ret; } static int recv_func(struct adapter *padapter, struct recv_frame *rframe) { int ret; struct rx_pkt_attrib *prxattrib = &rframe->attrib; struct security_priv *psecuritypriv = &padapter->securitypriv; struct mlme_priv *mlmepriv = &padapter->mlmepriv; struct recv_priv *recvpriv = &padapter->recvpriv; /* check if need to handle uc_swdec_pending_queue*/ if (check_fwstate(mlmepriv, WIFI_STATION_STATE) && psecuritypriv->busetkipkey) { struct recv_frame *pending_frame; while ((pending_frame = rtw_alloc_recvframe(&padapter->recvpriv.uc_swdec_pending_queue))) recv_func_posthandle(padapter, pending_frame); } ret = recv_func_prehandle(padapter, rframe); if (ret == _SUCCESS) { /* check if need to enqueue into uc_swdec_pending_queue*/ if (check_fwstate(mlmepriv, WIFI_STATION_STATE) && !is_multicast_ether_addr(prxattrib->ra) && prxattrib->encrypt > 0 && (prxattrib->bdecrypted == 0 || psecuritypriv->sw_decrypt) && psecuritypriv->ndisauthtype == Ndis802_11AuthModeWPAPSK && !psecuritypriv->busetkipkey) { rtw_enqueue_recvframe(rframe, &padapter->recvpriv.uc_swdec_pending_queue); if (recvpriv->free_recvframe_cnt < NR_RECVFRAME / 4) { /* to prevent from recvframe starvation, * get recvframe from uc_swdec_pending_queue to * free_recvframe_cnt */ rframe = rtw_alloc_recvframe(&padapter->recvpriv.uc_swdec_pending_queue); if (rframe) goto do_posthandle; } goto exit; } do_posthandle: ret = recv_func_posthandle(padapter, rframe); } exit: return ret; } s32 rtw_recv_entry(struct recv_frame *precvframe) { struct adapter *padapter; struct recv_priv *precvpriv; s32 ret = _SUCCESS; padapter = precvframe->adapter; precvpriv = &padapter->recvpriv; ret = recv_func(padapter, precvframe); if (ret == _FAIL) goto _recv_entry_drop; precvpriv->rx_pkts++; return ret; _recv_entry_drop: return ret; } #if LINUX_VERSION_CODE >= KERNEL_VERSION(4, 15, 0) void rtw_signal_stat_timer_hdl(struct timer_list *t) #else void rtw_signal_stat_timer_hdl(RTW_TIMER_HDL_ARGS) #endif { #if LINUX_VERSION_CODE >= KERNEL_VERSION(4, 15, 0) struct adapter *adapter = from_timer(adapter, t, recvpriv.signal_stat_timer); #else struct adapter *adapter = (struct adapter *)FunctionContext; #endif struct recv_priv *recvpriv = &adapter->recvpriv; u32 tmp_s, tmp_q; u8 avg_signal_strength = 0; u8 avg_signal_qual = 0; u8 _alpha = 3; /* this value is based on converging_constant = 5000 and sampling_interval = 1000 */ if (adapter->recvpriv.is_signal_dbg) { /* update the user specific value, signal_strength_dbg, to signal_strength, rssi */ adapter->recvpriv.signal_strength = adapter->recvpriv.signal_strength_dbg; adapter->recvpriv.rssi = (s8)translate_percentage_to_dbm((u8)adapter->recvpriv.signal_strength_dbg); } else { if (recvpriv->signal_strength_data.update_req == 0) {/* update_req is clear, means we got rx */ avg_signal_strength = recvpriv->signal_strength_data.avg_val; /* after avg_vals are accquired, we can re-stat the signal values */ recvpriv->signal_strength_data.update_req = 1; } if (recvpriv->signal_qual_data.update_req == 0) {/* update_req is clear, means we got rx */ avg_signal_qual = recvpriv->signal_qual_data.avg_val; /* after avg_vals are accquired, we can re-stat the signal values */ recvpriv->signal_qual_data.update_req = 1; } /* update value of signal_strength, rssi, signal_qual */ if (!check_fwstate(&adapter->mlmepriv, _FW_UNDER_SURVEY)) { tmp_s = (avg_signal_strength + (_alpha - 1) * recvpriv->signal_strength); if (tmp_s % _alpha) tmp_s = tmp_s / _alpha + 1; else tmp_s = tmp_s / _alpha; if (tmp_s > 100) tmp_s = 100; tmp_q = (avg_signal_qual + (_alpha - 1) * recvpriv->signal_qual); if (tmp_q % _alpha) tmp_q = tmp_q / _alpha + 1; else tmp_q = tmp_q / _alpha; if (tmp_q > 100) tmp_q = 100; recvpriv->signal_strength = tmp_s; recvpriv->rssi = (s8)translate_percentage_to_dbm(tmp_s); recvpriv->signal_qual = tmp_q; } } rtw_set_signal_stat_timer(recvpriv); }