/* * Copyright (c) 2017-2018 The Linux Foundation. All rights reserved. * * Permission to use, copy, modify, and/or distribute this software for * any purpose with or without fee is hereby granted, provided that the * above copyright notice and this permission notice appear in all * copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR * PERFORMANCE OF THIS SOFTWARE. */ #ifndef _HAL_API_MON_H_ #define _HAL_API_MON_H_ #include "qdf_types.h" #include "hal_internal.h" #define HAL_RX_OFFSET(block, field) block##_##field##_OFFSET #define HAL_RX_LSB(block, field) block##_##field##_LSB #define HAL_RX_MASk(block, field) block##_##field##_MASK #define HAL_RX_GET(_ptr, block, field) \ (((*((volatile uint32_t *)_ptr + (HAL_RX_OFFSET(block, field)>>2))) & \ HAL_RX_MASk(block, field)) >> \ HAL_RX_LSB(block, field)) #define HAL_RX_PHY_DATA_RADAR 0x01 #define HAL_SU_MU_CODING_LDPC 0x01 #define HAL_RX_FCS_LEN (4) #define KEY_EXTIV 0x20 #define HAL_RX_USER_TLV32_TYPE_OFFSET 0x00000000 #define HAL_RX_USER_TLV32_TYPE_LSB 1 #define HAL_RX_USER_TLV32_TYPE_MASK 0x000003FE #define HAL_RX_USER_TLV32_LEN_OFFSET 0x00000000 #define HAL_RX_USER_TLV32_LEN_LSB 10 #define HAL_RX_USER_TLV32_LEN_MASK 0x003FFC00 #define HAL_RX_USER_TLV32_USERID_OFFSET 0x00000000 #define HAL_RX_USER_TLV32_USERID_LSB 26 #define HAL_RX_USER_TLV32_USERID_MASK 0xFC000000 #define HAL_ALIGN(x, a) HAL_ALIGN_MASK(x, (a)-1) #define HAL_ALIGN_MASK(x, mask) (typeof(x))(((uint32)(x) + (mask)) & ~(mask)) #define HAL_RX_TLV32_HDR_SIZE 4 #define HAL_RX_GET_USER_TLV32_TYPE(rx_status_tlv_ptr) \ ((*((uint32_t *)(rx_status_tlv_ptr)) & \ HAL_RX_USER_TLV32_TYPE_MASK) >> \ HAL_RX_USER_TLV32_TYPE_LSB) #define HAL_RX_GET_USER_TLV32_LEN(rx_status_tlv_ptr) \ ((*((uint32_t *)(rx_status_tlv_ptr)) & \ HAL_RX_USER_TLV32_LEN_MASK) >> \ HAL_RX_USER_TLV32_LEN_LSB) #define HAL_RX_GET_USER_TLV32_USERID(rx_status_tlv_ptr) \ ((*((uint32_t *)(rx_status_tlv_ptr)) & \ HAL_RX_USER_TLV32_USERID_MASK) >> \ HAL_RX_USER_TLV32_USERID_LSB) #define HAL_TLV_STATUS_PPDU_NOT_DONE 0 #define HAL_TLV_STATUS_PPDU_DONE 1 #define HAL_TLV_STATUS_BUF_DONE 2 #define HAL_MAX_UL_MU_USERS 8 #define HAL_RX_PKT_TYPE_11A 0 #define HAL_RX_PKT_TYPE_11B 1 #define HAL_RX_PKT_TYPE_11N 2 #define HAL_RX_PKT_TYPE_11AC 3 #define HAL_RX_PKT_TYPE_11AX 4 #define HAL_RX_RECEPTION_TYPE_SU 0 #define HAL_RX_RECEPTION_TYPE_MU_MIMO 1 #define HAL_RX_RECEPTION_TYPE_OFDMA 2 #define HAL_RX_RECEPTION_TYPE_MU_OFDMA 3 /* Multiply rate by 2 to avoid float point * and get rate in units of 500kbps */ #define HAL_11B_RATE_0MCS 11*2 #define HAL_11B_RATE_1MCS 5.5*2 #define HAL_11B_RATE_2MCS 2*2 #define HAL_11B_RATE_3MCS 1*2 #define HAL_11B_RATE_4MCS 11*2 #define HAL_11B_RATE_5MCS 5.5*2 #define HAL_11B_RATE_6MCS 2*2 #define HAL_11A_RATE_0MCS 48*2 #define HAL_11A_RATE_1MCS 24*2 #define HAL_11A_RATE_2MCS 12*2 #define HAL_11A_RATE_3MCS 6*2 #define HAL_11A_RATE_4MCS 54*2 #define HAL_11A_RATE_5MCS 36*2 #define HAL_11A_RATE_6MCS 18*2 #define HAL_11A_RATE_7MCS 9*2 #define HE_GI_0_8 0 #define HE_GI_1_6 1 #define HE_GI_3_2 2 #define HT_SGI_PRESENT 0x80 #define HE_LTF_1_X 0 #define HE_LTF_2_X 1 #define HE_LTF_4_X 2 #define VHT_SIG_SU_NSS_MASK 0x7 #define HAL_TID_INVALID 31 #define HAL_AST_IDX_INVALID 0xFFFF #ifdef GET_MSDU_AGGREGATION #define HAL_RX_GET_MSDU_AGGREGATION(rx_desc, rs)\ {\ struct rx_msdu_end *rx_msdu_end;\ bool first_msdu, last_msdu; \ rx_msdu_end = &rx_desc->msdu_end_tlv.rx_msdu_end;\ first_msdu = HAL_RX_GET(rx_msdu_end, RX_MSDU_END_5, FIRST_MSDU);\ last_msdu = HAL_RX_GET(rx_msdu_end, RX_MSDU_END_5, LAST_MSDU);\ if (first_msdu && last_msdu)\ rs->rs_flags &= (~IEEE80211_AMSDU_FLAG);\ else\ rs->rs_flags |= (IEEE80211_AMSDU_FLAG); \ } \ #else #define HAL_RX_GET_MSDU_AGGREGATION(rx_desc, rs) #endif enum { HAL_HW_RX_DECAP_FORMAT_RAW = 0, HAL_HW_RX_DECAP_FORMAT_NWIFI, HAL_HW_RX_DECAP_FORMAT_ETH2, HAL_HW_RX_DECAP_FORMAT_8023, }; enum { DP_PPDU_STATUS_START, DP_PPDU_STATUS_DONE, }; static inline uint32_t HAL_RX_MON_HW_RX_DESC_SIZE(void) { /* return the HW_RX_DESC size */ return sizeof(struct rx_pkt_tlvs); } static inline uint8_t *HAL_RX_MON_DEST_GET_DESC(uint8_t *data) { return data; } static inline uint32_t HAL_RX_DESC_GET_MPDU_LENGTH_ERR(void *hw_desc_addr) { struct rx_attention *rx_attn; struct rx_pkt_tlvs *rx_desc = (struct rx_pkt_tlvs *)hw_desc_addr; rx_attn = &rx_desc->attn_tlv.rx_attn; return HAL_RX_GET(rx_attn, RX_ATTENTION_1, MPDU_LENGTH_ERR); } static inline uint32_t HAL_RX_DESC_GET_MPDU_FCS_ERR(void *hw_desc_addr) { struct rx_attention *rx_attn; struct rx_pkt_tlvs *rx_desc = (struct rx_pkt_tlvs *)hw_desc_addr; rx_attn = &rx_desc->attn_tlv.rx_attn; return HAL_RX_GET(rx_attn, RX_ATTENTION_1, FCS_ERR); } static inline uint32_t HAL_RX_DESC_GET_DECAP_FORMAT(void *hw_desc_addr) { struct rx_msdu_start *rx_msdu_start; struct rx_pkt_tlvs *rx_desc = (struct rx_pkt_tlvs *)hw_desc_addr; rx_msdu_start = &rx_desc->msdu_start_tlv.rx_msdu_start; return HAL_RX_GET(rx_msdu_start, RX_MSDU_START_2, DECAP_FORMAT); } static inline uint8_t * HAL_RX_DESC_GET_80211_HDR(void *hw_desc_addr) { uint8_t *rx_pkt_hdr; struct rx_pkt_tlvs *rx_desc = (struct rx_pkt_tlvs *)hw_desc_addr; rx_pkt_hdr = &rx_desc->pkt_hdr_tlv.rx_pkt_hdr[0]; return rx_pkt_hdr; } static inline uint32_t HAL_RX_HW_DESC_GET_PPDUID_GET(void *hw_desc_addr) { struct rx_mpdu_info *rx_mpdu_info; struct rx_pkt_tlvs *rx_desc = (struct rx_pkt_tlvs *)hw_desc_addr; rx_mpdu_info = &rx_desc->mpdu_start_tlv.rx_mpdu_start.rx_mpdu_info_details; return HAL_RX_GET(rx_mpdu_info, RX_MPDU_INFO_0, PHY_PPDU_ID); } /* TODO: Move all Rx descriptor functions to hal_rx.h to avoid duplication */ static inline uint32_t hal_rx_desc_is_first_msdu(void *hw_desc_addr) { struct rx_pkt_tlvs *rx_tlvs = (struct rx_pkt_tlvs *)hw_desc_addr; struct rx_msdu_end *msdu_end = &rx_tlvs->msdu_end_tlv.rx_msdu_end; return HAL_RX_GET(msdu_end, RX_MSDU_END_5, FIRST_MSDU); } #define HAL_RX_BUFFER_ADDR_31_0_GET(buff_addr_info) \ (_HAL_MS((*_OFFSET_TO_WORD_PTR(buff_addr_info, \ BUFFER_ADDR_INFO_0_BUFFER_ADDR_31_0_OFFSET)), \ BUFFER_ADDR_INFO_0_BUFFER_ADDR_31_0_MASK, \ BUFFER_ADDR_INFO_0_BUFFER_ADDR_31_0_LSB)) #define HAL_RX_REO_ENT_BUFFER_ADDR_39_32_GET(reo_ent_desc) \ (HAL_RX_BUFFER_ADDR_39_32_GET(& \ (((struct reo_entrance_ring *)reo_ent_desc) \ ->reo_level_mpdu_frame_info.msdu_link_desc_addr_info))) #define HAL_RX_REO_ENT_BUFFER_ADDR_31_0_GET(reo_ent_desc) \ (HAL_RX_BUFFER_ADDR_31_0_GET(& \ (((struct reo_entrance_ring *)reo_ent_desc) \ ->reo_level_mpdu_frame_info.msdu_link_desc_addr_info))) #define HAL_RX_REO_ENT_BUF_COOKIE_GET(reo_ent_desc) \ (HAL_RX_BUF_COOKIE_GET(& \ (((struct reo_entrance_ring *)reo_ent_desc) \ ->reo_level_mpdu_frame_info.msdu_link_desc_addr_info))) /** * hal_rx_reo_ent_buf_paddr_get: Gets the physical address and * cookie from the REO entrance ring element * * @ hal_rx_desc_cookie: Opaque cookie pointer used by HAL to get to * the current descriptor * @ buf_info: structure to return the buffer information * @ msdu_cnt: pointer to msdu count in MPDU * Return: void */ static inline void hal_rx_reo_ent_buf_paddr_get(void *rx_desc, struct hal_buf_info *buf_info, void **pp_buf_addr_info, uint32_t *msdu_cnt ) { struct reo_entrance_ring *reo_ent_ring = (struct reo_entrance_ring *)rx_desc; struct buffer_addr_info *buf_addr_info; struct rx_mpdu_desc_info *rx_mpdu_desc_info_details; uint32_t loop_cnt; rx_mpdu_desc_info_details = &reo_ent_ring->reo_level_mpdu_frame_info.rx_mpdu_desc_info_details; *msdu_cnt = HAL_RX_GET(rx_mpdu_desc_info_details, RX_MPDU_DESC_INFO_0, MSDU_COUNT); loop_cnt = HAL_RX_GET(reo_ent_ring, REO_ENTRANCE_RING_7, LOOPING_COUNT); buf_addr_info = &reo_ent_ring->reo_level_mpdu_frame_info.msdu_link_desc_addr_info; buf_info->paddr = (HAL_RX_BUFFER_ADDR_31_0_GET(buf_addr_info) | ((uint64_t) (HAL_RX_BUFFER_ADDR_39_32_GET(buf_addr_info)) << 32)); buf_info->sw_cookie = HAL_RX_BUF_COOKIE_GET(buf_addr_info); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "[%s][%d] ReoAddr=%pK, addrInfo=%pK, paddr=0x%llx, loopcnt=%d\n", __func__, __LINE__, reo_ent_ring, buf_addr_info, (unsigned long long)buf_info->paddr, loop_cnt); *pp_buf_addr_info = (void *)buf_addr_info; } static inline void hal_rx_mon_next_link_desc_get(void *rx_msdu_link_desc, struct hal_buf_info *buf_info, void **pp_buf_addr_info) { struct rx_msdu_link *msdu_link = (struct rx_msdu_link *)rx_msdu_link_desc; struct buffer_addr_info *buf_addr_info; buf_addr_info = &msdu_link->next_msdu_link_desc_addr_info; buf_info->paddr = (HAL_RX_BUFFER_ADDR_31_0_GET(buf_addr_info) | ((uint64_t) (HAL_RX_BUFFER_ADDR_39_32_GET(buf_addr_info)) << 32)); buf_info->sw_cookie = HAL_RX_BUF_COOKIE_GET(buf_addr_info); *pp_buf_addr_info = (void *)buf_addr_info; } /** * hal_rx_msdu_link_desc_set: Retrieves MSDU Link Descriptor to WBM * * @ soc : HAL version of the SOC pointer * @ src_srng_desc : void pointer to the WBM Release Ring descriptor * @ buf_addr_info : void pointer to the buffer_addr_info * * Return: void */ static inline void hal_rx_mon_msdu_link_desc_set(struct hal_soc *soc, void *src_srng_desc, void *buf_addr_info) { struct buffer_addr_info *wbm_srng_buffer_addr_info = (struct buffer_addr_info *)src_srng_desc; uint64_t paddr; struct buffer_addr_info *p_buffer_addr_info = (struct buffer_addr_info *)buf_addr_info; paddr = (HAL_RX_BUFFER_ADDR_31_0_GET(buf_addr_info) | ((uint64_t) (HAL_RX_BUFFER_ADDR_39_32_GET(buf_addr_info)) << 32)); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "[%s][%d] src_srng_desc=%pK, buf_addr=0x%llx, cookie=0x%llx\n", __func__, __LINE__, src_srng_desc, (unsigned long long)paddr, (unsigned long long)p_buffer_addr_info->sw_buffer_cookie); /* Structure copy !!! */ *wbm_srng_buffer_addr_info = *((struct buffer_addr_info *)buf_addr_info); } static inline uint32 hal_get_rx_msdu_link_desc_size(void) { return sizeof(struct rx_msdu_link); } enum { HAL_PKT_TYPE_OFDM = 0, HAL_PKT_TYPE_CCK, HAL_PKT_TYPE_HT, HAL_PKT_TYPE_VHT, HAL_PKT_TYPE_HE, }; enum { HAL_SGI_0_8_US, HAL_SGI_0_4_US, HAL_SGI_1_6_US, HAL_SGI_3_2_US, }; enum { HAL_FULL_RX_BW_20, HAL_FULL_RX_BW_40, HAL_FULL_RX_BW_80, HAL_FULL_RX_BW_160, }; enum { HAL_RX_TYPE_SU, HAL_RX_TYPE_MU_MIMO, HAL_RX_TYPE_MU_OFDMA, HAL_RX_TYPE_MU_OFDMA_MIMO, }; /** * enum * @HAL_RX_MON_PPDU_START: PPDU start TLV is decoded in HAL * @HAL_RX_MON_PPDU_END: PPDU end TLV is decided in HAL */ enum { HAL_RX_MON_PPDU_START = 0, HAL_RX_MON_PPDU_END, }; /** * hal_rx_mon_hw_desc_get_mpdu_status: Retrieve MPDU status * * @ hw_desc_addr: Start address of Rx HW TLVs * @ rs: Status for monitor mode * * Return: void */ static inline void hal_rx_mon_hw_desc_get_mpdu_status(void *hw_desc_addr, struct mon_rx_status *rs) { struct rx_msdu_start *rx_msdu_start; struct rx_pkt_tlvs *rx_desc = (struct rx_pkt_tlvs *)hw_desc_addr; uint32_t reg_value; static uint32_t sgi_hw_to_cdp[] = { CDP_SGI_0_8_US, CDP_SGI_0_4_US, CDP_SGI_1_6_US, CDP_SGI_3_2_US, }; rx_msdu_start = &rx_desc->msdu_start_tlv.rx_msdu_start; HAL_RX_GET_MSDU_AGGREGATION(rx_desc, rs); rs->ant_signal_db = HAL_RX_GET(rx_msdu_start, RX_MSDU_START_5, USER_RSSI); rs->is_stbc = HAL_RX_GET(rx_msdu_start, RX_MSDU_START_5, STBC); reg_value = HAL_RX_GET(rx_msdu_start, RX_MSDU_START_5, SGI); rs->sgi = sgi_hw_to_cdp[reg_value]; #if !defined(QCA_WIFI_QCA6290_11AX) rs->nr_ant = HAL_RX_GET(rx_msdu_start, RX_MSDU_START_5, NSS); #endif reg_value = HAL_RX_GET(rx_msdu_start, RX_MSDU_START_5, RECEPTION_TYPE); rs->beamformed = (reg_value == HAL_RX_RECEPTION_TYPE_MU_MIMO) ? 1 : 0; /* TODO: rs->beamformed should be set for SU beamforming also */ } struct hal_rx_ppdu_user_info { }; struct hal_rx_ppdu_common_info { uint32_t ppdu_id; uint32_t last_ppdu_id; uint32_t ppdu_timestamp; uint32_t mpdu_cnt_fcs_ok; uint32_t mpdu_cnt_fcs_err; }; struct hal_rx_msdu_payload_info { uint8_t *first_msdu_payload; uint32_t payload_len; }; struct hal_rx_ppdu_info { struct hal_rx_ppdu_common_info com_info; struct hal_rx_ppdu_user_info user_info[HAL_MAX_UL_MU_USERS]; struct mon_rx_status rx_status; struct hal_rx_msdu_payload_info msdu_info; /* status ring PPDU start and end state */ uint32_t rx_state; }; static inline uint32_t hal_get_rx_status_buf_size(void) { /* RX status buffer size is hard coded for now */ return 2048; } static inline uint8_t* hal_rx_status_get_next_tlv(uint8_t *rx_tlv) { uint32_t tlv_len, tlv_tag; tlv_len = HAL_RX_GET_USER_TLV32_LEN(rx_tlv); tlv_tag = HAL_RX_GET_USER_TLV32_TYPE(rx_tlv); /* The actual length of PPDU_END is the combined length of many PHY * TLVs that follow. Skip the TLV header and * rx_rxpcu_classification_overview that follows the header to get to * next TLV. */ if (tlv_tag == WIFIRX_PPDU_END_E) tlv_len = sizeof(struct rx_rxpcu_classification_overview); return (uint8_t *)(((unsigned long)(rx_tlv + tlv_len + HAL_RX_TLV32_HDR_SIZE + 3)) & (~((unsigned long)3))); } static inline uint32_t hal_rx_status_get_tlv_info(void *rx_tlv, struct hal_rx_ppdu_info *ppdu_info) { uint32_t tlv_tag, user_id, tlv_len, value; uint8_t group_id = 0; uint8_t he_dcm = 0; uint8_t he_stbc = 0; uint16_t he_gi = 0; uint16_t he_ltf = 0; tlv_tag = HAL_RX_GET_USER_TLV32_TYPE(rx_tlv); user_id = HAL_RX_GET_USER_TLV32_USERID(rx_tlv); tlv_len = HAL_RX_GET_USER_TLV32_LEN(rx_tlv); rx_tlv = (uint8_t *) rx_tlv + HAL_RX_TLV32_HDR_SIZE; switch (tlv_tag) { case WIFIRX_PPDU_START_E: QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "[%s][%d] ppdu_start_e len=%d", __func__, __LINE__, tlv_len); ppdu_info->com_info.ppdu_id = HAL_RX_GET(rx_tlv, RX_PPDU_START_0, PHY_PPDU_ID); /* channel number is set in PHY meta data */ ppdu_info->rx_status.chan_num = HAL_RX_GET(rx_tlv, RX_PPDU_START_1, SW_PHY_META_DATA); ppdu_info->com_info.ppdu_timestamp = HAL_RX_GET(rx_tlv, RX_PPDU_START_2, PPDU_START_TIMESTAMP); ppdu_info->rx_state = HAL_RX_MON_PPDU_START; break; case WIFIRX_PPDU_START_USER_INFO_E: break; case WIFIRX_PPDU_END_E: QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "[%s][%d] ppdu_end_e len=%d", __func__, __LINE__, tlv_len); /* This is followed by sub-TLVs of PPDU_END */ ppdu_info->rx_state = HAL_RX_MON_PPDU_END; break; case WIFIRXPCU_PPDU_END_INFO_E: ppdu_info->rx_status.tsft = HAL_RX_GET(rx_tlv, RXPCU_PPDU_END_INFO_1, WB_TIMESTAMP_UPPER_32); ppdu_info->rx_status.tsft = (ppdu_info->rx_status.tsft << 32) | HAL_RX_GET(rx_tlv, RXPCU_PPDU_END_INFO_0, WB_TIMESTAMP_LOWER_32); ppdu_info->rx_status.duration = HAL_RX_GET(rx_tlv, RXPCU_PPDU_END_INFO_8, RX_PPDU_DURATION); break; case WIFIRX_PPDU_END_USER_STATS_E: { unsigned long tid = 0; uint16_t seq = 0; ppdu_info->rx_status.ast_index = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_4, AST_INDEX); tid = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_12, RECEIVED_QOS_DATA_TID_BITMAP); ppdu_info->rx_status.tid = qdf_find_first_bit(&tid, sizeof(tid)*8); if (ppdu_info->rx_status.tid == (sizeof(tid) * 8)) ppdu_info->rx_status.tid = HAL_TID_INVALID; ppdu_info->rx_status.tcp_msdu_count = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_9, TCP_MSDU_COUNT) + HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_10, TCP_ACK_MSDU_COUNT); ppdu_info->rx_status.udp_msdu_count = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_9, UDP_MSDU_COUNT); ppdu_info->rx_status.other_msdu_count = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_10, OTHER_MSDU_COUNT); ppdu_info->rx_status.frame_control_info_valid = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_3, DATA_SEQUENCE_CONTROL_INFO_VALID); seq = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_5, FIRST_DATA_SEQ_CTRL); if (ppdu_info->rx_status.frame_control_info_valid) ppdu_info->rx_status.first_data_seq_ctrl = seq; ppdu_info->rx_status.preamble_type = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_3, HT_CONTROL_FIELD_PKT_TYPE); switch (ppdu_info->rx_status.preamble_type) { case HAL_RX_PKT_TYPE_11N: ppdu_info->rx_status.ht_flags = 1; ppdu_info->rx_status.rtap_flags |= HT_SGI_PRESENT; break; case HAL_RX_PKT_TYPE_11AC: ppdu_info->rx_status.vht_flags = 1; break; case HAL_RX_PKT_TYPE_11AX: ppdu_info->rx_status.he_flags = 1; break; default: break; } ppdu_info->com_info.mpdu_cnt_fcs_ok = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_3, MPDU_CNT_FCS_OK); ppdu_info->com_info.mpdu_cnt_fcs_err = HAL_RX_GET(rx_tlv, RX_PPDU_END_USER_STATS_2, MPDU_CNT_FCS_ERR); if ((ppdu_info->com_info.mpdu_cnt_fcs_ok | ppdu_info->com_info.mpdu_cnt_fcs_err) > 1) ppdu_info->rx_status.rs_flags |= IEEE80211_AMPDU_FLAG; else ppdu_info->rx_status.rs_flags &= (~IEEE80211_AMPDU_FLAG); break; } case WIFIRX_PPDU_END_USER_STATS_EXT_E: break; case WIFIRX_PPDU_END_STATUS_DONE_E: return HAL_TLV_STATUS_PPDU_DONE; case WIFIDUMMY_E: return HAL_TLV_STATUS_BUF_DONE; case WIFIPHYRX_HT_SIG_E: { uint8_t *ht_sig_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_HT_SIG_0, HT_SIG_INFO_PHYRX_HT_SIG_INFO_DETAILS); value = HAL_RX_GET(ht_sig_info, HT_SIG_INFO_1, FEC_CODING); ppdu_info->rx_status.ldpc = (value == HAL_SU_MU_CODING_LDPC) ? 1 : 0; ppdu_info->rx_status.mcs = HAL_RX_GET(ht_sig_info, HT_SIG_INFO_0, MCS); ppdu_info->rx_status.bw = HAL_RX_GET(ht_sig_info, HT_SIG_INFO_0, CBW); ppdu_info->rx_status.sgi = HAL_RX_GET(ht_sig_info, HT_SIG_INFO_1, SHORT_GI); break; } case WIFIPHYRX_L_SIG_B_E: { uint8_t *l_sig_b_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_L_SIG_B_0, L_SIG_B_INFO_PHYRX_L_SIG_B_INFO_DETAILS); value = HAL_RX_GET(l_sig_b_info, L_SIG_B_INFO_0, RATE); switch (value) { case 1: ppdu_info->rx_status.rate = HAL_11B_RATE_3MCS; break; case 2: ppdu_info->rx_status.rate = HAL_11B_RATE_2MCS; break; case 3: ppdu_info->rx_status.rate = HAL_11B_RATE_1MCS; break; case 4: ppdu_info->rx_status.rate = HAL_11B_RATE_0MCS; break; case 5: ppdu_info->rx_status.rate = HAL_11B_RATE_6MCS; break; case 6: ppdu_info->rx_status.rate = HAL_11B_RATE_5MCS; break; case 7: ppdu_info->rx_status.rate = HAL_11B_RATE_4MCS; break; default: break; } ppdu_info->rx_status.cck_flag = 1; break; } case WIFIPHYRX_L_SIG_A_E: { uint8_t *l_sig_a_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_L_SIG_A_0, L_SIG_A_INFO_PHYRX_L_SIG_A_INFO_DETAILS); value = HAL_RX_GET(l_sig_a_info, L_SIG_A_INFO_0, RATE); switch (value) { case 8: ppdu_info->rx_status.rate = HAL_11A_RATE_0MCS; break; case 9: ppdu_info->rx_status.rate = HAL_11A_RATE_1MCS; break; case 10: ppdu_info->rx_status.rate = HAL_11A_RATE_2MCS; break; case 11: ppdu_info->rx_status.rate = HAL_11A_RATE_3MCS; break; case 12: ppdu_info->rx_status.rate = HAL_11A_RATE_4MCS; break; case 13: ppdu_info->rx_status.rate = HAL_11A_RATE_5MCS; break; case 14: ppdu_info->rx_status.rate = HAL_11A_RATE_6MCS; break; case 15: ppdu_info->rx_status.rate = HAL_11A_RATE_7MCS; break; default: break; } ppdu_info->rx_status.ofdm_flag = 1; break; } case WIFIPHYRX_VHT_SIG_A_E: { uint8_t *vht_sig_a_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_VHT_SIG_A_0, VHT_SIG_A_INFO_PHYRX_VHT_SIG_A_INFO_DETAILS); value = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_1, SU_MU_CODING); ppdu_info->rx_status.ldpc = (value == HAL_SU_MU_CODING_LDPC) ? 1 : 0; group_id = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_0, GROUP_ID); ppdu_info->rx_status.vht_flag_values5 = group_id; ppdu_info->rx_status.mcs = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_1, MCS); ppdu_info->rx_status.sgi = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_1, GI_SETTING); #if !defined(QCA_WIFI_QCA6290_11AX) value = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_0, N_STS); ppdu_info->rx_status.nss = ((value & VHT_SIG_SU_NSS_MASK) + 1); #else ppdu_info->rx_status.nss = 0; #endif ppdu_info->rx_status.vht_flag_values3[0] = (((ppdu_info->rx_status.mcs) << 4) | ppdu_info->rx_status.nss); ppdu_info->rx_status.bw = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_0, BANDWIDTH); ppdu_info->rx_status.vht_flag_values2 = ppdu_info->rx_status.bw; ppdu_info->rx_status.vht_flag_values4 = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_1, SU_MU_CODING); ppdu_info->rx_status.beamformed = HAL_RX_GET(vht_sig_a_info, VHT_SIG_A_INFO_1, BEAMFORMED); break; } case WIFIPHYRX_HE_SIG_A_SU_E: { uint8_t *he_sig_a_su_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_HE_SIG_A_SU_0, HE_SIG_A_SU_INFO_PHYRX_HE_SIG_A_SU_INFO_DETAILS); ppdu_info->rx_status.he_flags = 1; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, FORMAT_INDICATION); if (value == 0) { ppdu_info->rx_status.he_data1 = QDF_MON_STATUS_HE_TRIG_FORMAT_TYPE; } else { ppdu_info->rx_status.he_data1 = QDF_MON_STATUS_HE_SU_FORMAT_TYPE; } /* data1 */ ppdu_info->rx_status.he_data1 |= QDF_MON_STATUS_HE_BSS_COLOR_KNOWN | QDF_MON_STATUS_HE_BEAM_CHANGE_KNOWN | QDF_MON_STATUS_HE_DL_UL_KNOWN | QDF_MON_STATUS_HE_MCS_KNOWN | QDF_MON_STATUS_HE_DCM_KNOWN | QDF_MON_STATUS_HE_CODING_KNOWN | QDF_MON_STATUS_HE_LDPC_EXTRA_SYMBOL_KNOWN | QDF_MON_STATUS_HE_STBC_KNOWN | QDF_MON_STATUS_HE_DATA_BW_RU_KNOWN | QDF_MON_STATUS_HE_DOPPLER_KNOWN; /* data2 */ ppdu_info->rx_status.he_data2 = QDF_MON_STATUS_HE_GI_KNOWN; ppdu_info->rx_status.he_data2 |= QDF_MON_STATUS_TXBF_KNOWN | QDF_MON_STATUS_PE_DISAMBIGUITY_KNOWN | QDF_MON_STATUS_TXOP_KNOWN | QDF_MON_STATUS_LTF_SYMBOLS_KNOWN | QDF_MON_STATUS_PRE_FEC_PADDING_KNOWN | QDF_MON_STATUS_MIDABLE_PERIODICITY_KNOWN; /* data3 */ value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, BSS_COLOR_ID); ppdu_info->rx_status.he_data3 = value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, BEAM_CHANGE); value = value << QDF_MON_STATUS_BEAM_CHANGE_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, DL_UL_FLAG); value = value << QDF_MON_STATUS_DL_UL_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, TRANSMIT_MCS); ppdu_info->rx_status.mcs = value; value = value << QDF_MON_STATUS_TRANSMIT_MCS_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, DCM); he_dcm = value; value = value << QDF_MON_STATUS_DCM_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, CODING); value = value << QDF_MON_STATUS_CODING_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, LDPC_EXTRA_SYMBOL); value = value << QDF_MON_STATUS_LDPC_EXTRA_SYMBOL_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, STBC); he_stbc = value; value = value << QDF_MON_STATUS_STBC_SHIFT; ppdu_info->rx_status.he_data3 |= value; /* data4 */ value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, SPATIAL_REUSE); ppdu_info->rx_status.he_data4 = value; /* data5 */ value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, TRANSMIT_BW); ppdu_info->rx_status.he_data5 = value; ppdu_info->rx_status.bw = value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, CP_LTF_SIZE); switch (value) { case 0: he_gi = HE_GI_0_8; he_ltf = HE_LTF_1_X; break; case 1: he_gi = HE_GI_0_8; he_ltf = HE_LTF_2_X; break; case 2: he_gi = HE_GI_1_6; he_ltf = HE_LTF_2_X; break; case 3: if (he_dcm && he_stbc) { he_gi = HE_GI_0_8; he_ltf = HE_LTF_4_X; } else { he_gi = HE_GI_3_2; he_ltf = HE_LTF_4_X; } break; } ppdu_info->rx_status.sgi = he_gi; value = he_gi << QDF_MON_STATUS_GI_SHIFT; ppdu_info->rx_status.he_data5 |= value; value = he_ltf << QDF_MON_STATUS_HE_LTF_SHIFT; ppdu_info->rx_status.he_data5 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, PACKET_EXTENSION_A_FACTOR); value = value << QDF_MON_STATUS_PRE_FEC_PAD_SHIFT; ppdu_info->rx_status.he_data5 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, TXBF); value = value << QDF_MON_STATUS_TXBF_SHIFT; ppdu_info->rx_status.he_data5 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, PACKET_EXTENSION_PE_DISAMBIGUITY); value = value << QDF_MON_STATUS_PE_DISAMBIGUITY_SHIFT; ppdu_info->rx_status.he_data5 |= value; /* data6 */ value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_0, NSTS); value++; ppdu_info->rx_status.nss = value; ppdu_info->rx_status.he_data6 = value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, DOPPLER_INDICATION); value = value << QDF_MON_STATUS_DOPPLER_SHIFT; ppdu_info->rx_status.he_data6 |= value; value = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, TXOP_DURATION); value = value << QDF_MON_STATUS_TXOP_SHIFT; ppdu_info->rx_status.he_data6 |= value; ppdu_info->rx_status.beamformed = HAL_RX_GET(he_sig_a_su_info, HE_SIG_A_SU_INFO_1, TXBF); break; } case WIFIPHYRX_HE_SIG_A_MU_DL_E: { uint8_t *he_sig_a_mu_dl_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_HE_SIG_A_MU_DL_0, HE_SIG_A_MU_DL_INFO_PHYRX_HE_SIG_A_MU_DL_INFO_DETAILS); ppdu_info->rx_status.he_mu_flags = 1; /* HE Flags */ /*data1*/ ppdu_info->rx_status.he_data1 = QDF_MON_STATUS_HE_MU_FORMAT_TYPE; ppdu_info->rx_status.he_data1 |= QDF_MON_STATUS_HE_BSS_COLOR_KNOWN | QDF_MON_STATUS_HE_DL_UL_KNOWN | QDF_MON_STATUS_HE_LDPC_EXTRA_SYMBOL_KNOWN | QDF_MON_STATUS_HE_STBC_KNOWN | QDF_MON_STATUS_HE_DATA_BW_RU_KNOWN | QDF_MON_STATUS_HE_DOPPLER_KNOWN; /* data2 */ ppdu_info->rx_status.he_data2 = QDF_MON_STATUS_HE_GI_KNOWN; ppdu_info->rx_status.he_data2 |= QDF_MON_STATUS_LTF_SYMBOLS_KNOWN | QDF_MON_STATUS_PRE_FEC_PADDING_KNOWN | QDF_MON_STATUS_PE_DISAMBIGUITY_KNOWN | QDF_MON_STATUS_TXOP_KNOWN | QDF_MON_STATUS_MIDABLE_PERIODICITY_KNOWN; /*data3*/ value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, BSS_COLOR_ID); ppdu_info->rx_status.he_data3 = value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, DL_UL_FLAG); value = value << QDF_MON_STATUS_DL_UL_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_1, LDPC_EXTRA_SYMBOL); value = value << QDF_MON_STATUS_LDPC_EXTRA_SYMBOL_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_1, STBC); he_stbc = value; value = value << QDF_MON_STATUS_STBC_SHIFT; ppdu_info->rx_status.he_data3 |= value; /*data4*/ value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, SPATIAL_REUSE); ppdu_info->rx_status.he_data4 = value; /*data5*/ value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, TRANSMIT_BW); ppdu_info->rx_status.he_data5 = value; ppdu_info->rx_status.bw = value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, CP_LTF_SIZE); switch (value) { case 0: he_gi = HE_GI_0_8; he_ltf = HE_LTF_4_X; break; case 1: he_gi = HE_GI_0_8; he_ltf = HE_LTF_2_X; break; case 2: he_gi = HE_GI_1_6; he_ltf = HE_LTF_2_X; break; case 3: he_gi = HE_GI_3_2; he_ltf = HE_LTF_4_X; break; } ppdu_info->rx_status.sgi = he_gi; value = he_gi << QDF_MON_STATUS_GI_SHIFT; ppdu_info->rx_status.he_data5 |= value; value = he_ltf << QDF_MON_STATUS_HE_LTF_SHIFT; ppdu_info->rx_status.he_data5 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_1, PACKET_EXTENSION_A_FACTOR); value = value << QDF_MON_STATUS_PRE_FEC_PAD_SHIFT; ppdu_info->rx_status.he_data5 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_1, PACKET_EXTENSION_PE_DISAMBIGUITY); value = value << QDF_MON_STATUS_PE_DISAMBIGUITY_SHIFT; ppdu_info->rx_status.he_data5 |= value; /*data6*/ value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, DOPPLER_INDICATION); value = value << QDF_MON_STATUS_DOPPLER_SHIFT; ppdu_info->rx_status.he_data6 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_1, TXOP_DURATION); value = value << QDF_MON_STATUS_TXOP_SHIFT; ppdu_info->rx_status.he_data6 |= value; /* HE-MU Flags */ /* HE-MU-flags1 */ ppdu_info->rx_status.he_flags1 = QDF_MON_STATUS_SIG_B_MCS_KNOWN | QDF_MON_STATUS_SIG_B_DCM_KNOWN | QDF_MON_STATUS_SIG_B_COMPRESSION_FLAG_1_KNOWN | QDF_MON_STATUS_SIG_B_SYM_NUM_KNOWN | QDF_MON_STATUS_RU_0_KNOWN; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, MCS_OF_SIG_B); ppdu_info->rx_status.he_flags1 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, DCM_OF_SIG_B); value = value << QDF_MON_STATUS_DCM_FLAG_1_SHIFT; ppdu_info->rx_status.he_flags1 |= value; /* HE-MU-flags2 */ ppdu_info->rx_status.he_flags2 = QDF_MON_STATUS_BW_KNOWN; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, TRANSMIT_BW); ppdu_info->rx_status.he_flags2 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, COMP_MODE_SIG_B); value = value << QDF_MON_STATUS_SIG_B_COMPRESSION_FLAG_2_SHIFT; ppdu_info->rx_status.he_flags2 |= value; value = HAL_RX_GET(he_sig_a_mu_dl_info, HE_SIG_A_MU_DL_INFO_0, NUM_SIG_B_SYMBOLS); value = value - 1; value = value << QDF_MON_STATUS_NUM_SIG_B_SYMBOLS_SHIFT; ppdu_info->rx_status.he_flags2 |= value; break; } case WIFIPHYRX_HE_SIG_B1_MU_E: { uint8_t *he_sig_b1_mu_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_HE_SIG_B1_MU_0, HE_SIG_B1_MU_INFO_PHYRX_HE_SIG_B1_MU_INFO_DETAILS); ppdu_info->rx_status.he_sig_b_common_known |= QDF_MON_STATUS_HE_SIG_B_COMMON_KNOWN_RU0; /* TODO: Check on the availability of other fields in * sig_b_common */ value = HAL_RX_GET(he_sig_b1_mu_info, HE_SIG_B1_MU_INFO_0, RU_ALLOCATION); ppdu_info->rx_status.he_RU[0] = value; break; } case WIFIPHYRX_HE_SIG_B2_MU_E: { uint8_t *he_sig_b2_mu_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_HE_SIG_B2_MU_0, HE_SIG_B2_MU_INFO_PHYRX_HE_SIG_B2_MU_INFO_DETAILS); /* * Not all "HE" fields can be updated from * WIFIPHYRX_HE_SIG_A_MU_DL_E TLV. Use WIFIPHYRX_HE_SIG_B2_MU_E * to populate rest of the "HE" fields for MU scenarios. */ /* HE-data1 */ ppdu_info->rx_status.he_data1 |= QDF_MON_STATUS_HE_MCS_KNOWN | QDF_MON_STATUS_HE_CODING_KNOWN; /* HE-data2 */ /* HE-data3 */ value = HAL_RX_GET(he_sig_b2_mu_info, HE_SIG_B2_MU_INFO_0, STA_MCS); ppdu_info->rx_status.mcs = value; value = value << QDF_MON_STATUS_TRANSMIT_MCS_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_b2_mu_info, HE_SIG_B2_MU_INFO_0, STA_CODING); value = value << QDF_MON_STATUS_CODING_SHIFT; ppdu_info->rx_status.he_data3 |= value; /* HE-data4 */ value = HAL_RX_GET(he_sig_b2_mu_info, HE_SIG_B2_MU_INFO_0, STA_ID); value = value << QDF_MON_STATUS_STA_ID_SHIFT; ppdu_info->rx_status.he_data4 |= value; /* HE-data5 */ /* HE-data6 */ value = HAL_RX_GET(he_sig_b2_mu_info, HE_SIG_B2_MU_INFO_0, NSTS); /* value n indicates n+1 spatial streams */ value++; ppdu_info->rx_status.nss = value; ppdu_info->rx_status.he_data6 |= value; break; } case WIFIPHYRX_HE_SIG_B2_OFDMA_E: { uint8_t *he_sig_b2_ofdma_info = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_HE_SIG_B2_OFDMA_0, HE_SIG_B2_OFDMA_INFO_PHYRX_HE_SIG_B2_OFDMA_INFO_DETAILS); /* * Not all "HE" fields can be updated from * WIFIPHYRX_HE_SIG_A_MU_DL_E TLV. Use WIFIPHYRX_HE_SIG_B2_MU_E * to populate rest of "HE" fields for MU OFDMA scenarios. */ /* HE-data1 */ ppdu_info->rx_status.he_data1 |= QDF_MON_STATUS_HE_MCS_KNOWN | QDF_MON_STATUS_HE_DCM_KNOWN | QDF_MON_STATUS_HE_CODING_KNOWN; /* HE-data2 */ ppdu_info->rx_status.he_data2 |= QDF_MON_STATUS_TXBF_KNOWN; /* HE-data3 */ value = HAL_RX_GET(he_sig_b2_ofdma_info, HE_SIG_B2_OFDMA_INFO_0, STA_MCS); ppdu_info->rx_status.mcs = value; value = value << QDF_MON_STATUS_TRANSMIT_MCS_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_b2_ofdma_info, HE_SIG_B2_OFDMA_INFO_0, STA_DCM); he_dcm = value; value = value << QDF_MON_STATUS_DCM_SHIFT; ppdu_info->rx_status.he_data3 |= value; value = HAL_RX_GET(he_sig_b2_ofdma_info, HE_SIG_B2_OFDMA_INFO_0, STA_CODING); value = value << QDF_MON_STATUS_CODING_SHIFT; ppdu_info->rx_status.he_data3 |= value; /* HE-data4 */ value = HAL_RX_GET(he_sig_b2_ofdma_info, HE_SIG_B2_OFDMA_INFO_0, STA_ID); value = value << QDF_MON_STATUS_STA_ID_SHIFT; ppdu_info->rx_status.he_data4 |= value; /* HE-data5 */ value = HAL_RX_GET(he_sig_b2_ofdma_info, HE_SIG_B2_OFDMA_INFO_0, TXBF); value = value << QDF_MON_STATUS_TXBF_SHIFT; ppdu_info->rx_status.he_data5 |= value; /* HE-data6 */ value = HAL_RX_GET(he_sig_b2_ofdma_info, HE_SIG_B2_OFDMA_INFO_0, NSTS); /* value n indicates n+1 spatial streams */ value++; ppdu_info->rx_status.nss = value; ppdu_info->rx_status.he_data6 |= value; break; } case WIFIPHYRX_RSSI_LEGACY_E: { uint8_t *rssi_info_tlv = (uint8_t *)rx_tlv + HAL_RX_OFFSET(PHYRX_RSSI_LEGACY_3, RECEIVE_RSSI_INFO_PRE_RSSI_INFO_DETAILS); ppdu_info->rx_status.rssi_comb = HAL_RX_GET(rx_tlv, PHYRX_RSSI_LEGACY_35, RSSI_COMB); ppdu_info->rx_status.bw = HAL_RX_GET(rx_tlv, #if !defined(QCA_WIFI_QCA6290_11AX) PHYRX_RSSI_LEGACY_35, RECEIVE_BANDWIDTH); #else PHYRX_RSSI_LEGACY_0, RECEIVE_BANDWIDTH); #endif ppdu_info->rx_status.he_re = 0; ppdu_info->rx_status.reception_type = HAL_RX_GET(rx_tlv, PHYRX_RSSI_LEGACY_0, RECEPTION_TYPE); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_0, RSSI_PRI20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_PRI20_CHAIN0: %d\n", value); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_0, RSSI_EXT20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_EXT20_CHAIN0: %d\n", value); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_0, RSSI_EXT40_LOW20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_EXT40_LOW20_CHAIN0: %d\n", value); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_0, RSSI_EXT40_HIGH20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_EXT40_HIGH20_CHAIN0: %d\n", value); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_1, RSSI_EXT80_LOW20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_EXT80_LOW20_CHAIN0: %d\n", value); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_1, RSSI_EXT80_LOW_HIGH20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_EXT80_LOW_HIGH20_CHAIN0: %d\n", value); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_1, RSSI_EXT80_HIGH_LOW20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_EXT80_HIGH_LOW20_CHAIN0: %d\n", value); value = HAL_RX_GET(rssi_info_tlv, RECEIVE_RSSI_INFO_1, RSSI_EXT80_HIGH20_CHAIN0); QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "RSSI_EXT80_HIGH20_CHAIN0: %d\n", value); break; } case WIFIRX_HEADER_E: ppdu_info->msdu_info.first_msdu_payload = rx_tlv; ppdu_info->msdu_info.payload_len = tlv_len; break; case WIFIRX_MPDU_START_E: { uint8_t *rx_mpdu_start = (uint8_t *)rx_tlv + HAL_RX_OFFSET(RX_MPDU_START_0, RX_MPDU_INFO_RX_MPDU_INFO_DETAILS); uint32_t ppdu_id = HAL_RX_GET(rx_mpdu_start, RX_MPDU_INFO_0, PHY_PPDU_ID); if (ppdu_info->rx_status.prev_ppdu_id != ppdu_id) { ppdu_info->rx_status.prev_ppdu_id = ppdu_id; ppdu_info->rx_status.ppdu_len = HAL_RX_GET(rx_mpdu_start, RX_MPDU_INFO_13, MPDU_LENGTH); } else { ppdu_info->rx_status.ppdu_len += HAL_RX_GET(rx_mpdu_start, RX_MPDU_INFO_13, MPDU_LENGTH); } break; } case 0: return HAL_TLV_STATUS_PPDU_DONE; default: break; } QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG, "%s TLV type: %d, TLV len:%d", __func__, tlv_tag, tlv_len); return HAL_TLV_STATUS_PPDU_NOT_DONE; } static inline uint32_t hal_get_rx_status_done_tlv_size(void *hal_soc) { return HAL_RX_TLV32_HDR_SIZE; } static inline QDF_STATUS hal_get_rx_status_done(uint8_t *rx_tlv) { uint32_t tlv_tag; tlv_tag = HAL_RX_GET_USER_TLV32_TYPE(rx_tlv); if (tlv_tag == WIFIRX_STATUS_BUFFER_DONE_E) return QDF_STATUS_SUCCESS; else return QDF_STATUS_E_EMPTY; } static inline QDF_STATUS hal_clear_rx_status_done(uint8_t *rx_tlv) { *(uint32_t *)rx_tlv = 0; return QDF_STATUS_SUCCESS; } #endif