/* SPDX-License-Identifier: BSD-3-Clause-Clear */ /* * Copyright (c) 2018-2019 The Linux Foundation. All rights reserved. */ #ifndef DEBUG_HTT_STATS_H #define DEBUG_HTT_STATS_H #define HTT_STATS_COOKIE_LSB GENMASK_ULL(31, 0) #define HTT_STATS_COOKIE_MSB GENMASK_ULL(63, 32) #define HTT_STATS_MAGIC_VALUE 0xF0F0F0F0 enum htt_tlv_tag_t { HTT_STATS_TX_PDEV_CMN_TAG = 0, HTT_STATS_TX_PDEV_UNDERRUN_TAG = 1, HTT_STATS_TX_PDEV_SIFS_TAG = 2, HTT_STATS_TX_PDEV_FLUSH_TAG = 3, HTT_STATS_TX_PDEV_PHY_ERR_TAG = 4, HTT_STATS_STRING_TAG = 5, HTT_STATS_TX_HWQ_CMN_TAG = 6, HTT_STATS_TX_HWQ_DIFS_LATENCY_TAG = 7, HTT_STATS_TX_HWQ_CMD_RESULT_TAG = 8, HTT_STATS_TX_HWQ_CMD_STALL_TAG = 9, HTT_STATS_TX_HWQ_FES_STATUS_TAG = 10, HTT_STATS_TX_TQM_GEN_MPDU_TAG = 11, HTT_STATS_TX_TQM_LIST_MPDU_TAG = 12, HTT_STATS_TX_TQM_LIST_MPDU_CNT_TAG = 13, HTT_STATS_TX_TQM_CMN_TAG = 14, HTT_STATS_TX_TQM_PDEV_TAG = 15, HTT_STATS_TX_TQM_CMDQ_STATUS_TAG = 16, HTT_STATS_TX_DE_EAPOL_PACKETS_TAG = 17, HTT_STATS_TX_DE_CLASSIFY_FAILED_TAG = 18, HTT_STATS_TX_DE_CLASSIFY_STATS_TAG = 19, HTT_STATS_TX_DE_CLASSIFY_STATUS_TAG = 20, HTT_STATS_TX_DE_ENQUEUE_PACKETS_TAG = 21, HTT_STATS_TX_DE_ENQUEUE_DISCARD_TAG = 22, HTT_STATS_TX_DE_CMN_TAG = 23, HTT_STATS_RING_IF_TAG = 24, HTT_STATS_TX_PDEV_MU_MIMO_STATS_TAG = 25, HTT_STATS_SFM_CMN_TAG = 26, HTT_STATS_SRING_STATS_TAG = 27, HTT_STATS_RX_PDEV_FW_STATS_TAG = 28, HTT_STATS_RX_PDEV_FW_RING_MPDU_ERR_TAG = 29, HTT_STATS_RX_PDEV_FW_MPDU_DROP_TAG = 30, HTT_STATS_RX_SOC_FW_STATS_TAG = 31, HTT_STATS_RX_SOC_FW_REFILL_RING_EMPTY_TAG = 32, HTT_STATS_RX_SOC_FW_REFILL_RING_NUM_REFILL_TAG = 33, HTT_STATS_TX_PDEV_RATE_STATS_TAG = 34, HTT_STATS_RX_PDEV_RATE_STATS_TAG = 35, HTT_STATS_TX_PDEV_SCHEDULER_TXQ_STATS_TAG = 36, HTT_STATS_TX_SCHED_CMN_TAG = 37, HTT_STATS_TX_PDEV_MUMIMO_MPDU_STATS_TAG = 38, HTT_STATS_SCHED_TXQ_CMD_POSTED_TAG = 39, HTT_STATS_RING_IF_CMN_TAG = 40, HTT_STATS_SFM_CLIENT_USER_TAG = 41, HTT_STATS_SFM_CLIENT_TAG = 42, HTT_STATS_TX_TQM_ERROR_STATS_TAG = 43, HTT_STATS_SCHED_TXQ_CMD_REAPED_TAG = 44, HTT_STATS_SRING_CMN_TAG = 45, HTT_STATS_TX_SELFGEN_AC_ERR_STATS_TAG = 46, HTT_STATS_TX_SELFGEN_CMN_STATS_TAG = 47, HTT_STATS_TX_SELFGEN_AC_STATS_TAG = 48, HTT_STATS_TX_SELFGEN_AX_STATS_TAG = 49, HTT_STATS_TX_SELFGEN_AX_ERR_STATS_TAG = 50, HTT_STATS_TX_HWQ_MUMIMO_SCH_STATS_TAG = 51, HTT_STATS_TX_HWQ_MUMIMO_MPDU_STATS_TAG = 52, HTT_STATS_TX_HWQ_MUMIMO_CMN_STATS_TAG = 53, HTT_STATS_HW_INTR_MISC_TAG = 54, HTT_STATS_HW_WD_TIMEOUT_TAG = 55, HTT_STATS_HW_PDEV_ERRS_TAG = 56, HTT_STATS_COUNTER_NAME_TAG = 57, HTT_STATS_TX_TID_DETAILS_TAG = 58, HTT_STATS_RX_TID_DETAILS_TAG = 59, HTT_STATS_PEER_STATS_CMN_TAG = 60, HTT_STATS_PEER_DETAILS_TAG = 61, HTT_STATS_PEER_TX_RATE_STATS_TAG = 62, HTT_STATS_PEER_RX_RATE_STATS_TAG = 63, HTT_STATS_PEER_MSDU_FLOWQ_TAG = 64, HTT_STATS_TX_DE_COMPL_STATS_TAG = 65, HTT_STATS_WHAL_TX_TAG = 66, HTT_STATS_TX_PDEV_SIFS_HIST_TAG = 67, HTT_STATS_RX_PDEV_FW_STATS_PHY_ERR_TAG = 68, HTT_STATS_TX_TID_DETAILS_V1_TAG = 69, HTT_STATS_PDEV_CCA_1SEC_HIST_TAG = 70, HTT_STATS_PDEV_CCA_100MSEC_HIST_TAG = 71, HTT_STATS_PDEV_CCA_STAT_CUMULATIVE_TAG = 72, HTT_STATS_PDEV_CCA_COUNTERS_TAG = 73, HTT_STATS_TX_PDEV_MPDU_STATS_TAG = 74, HTT_STATS_PDEV_TWT_SESSIONS_TAG = 75, HTT_STATS_PDEV_TWT_SESSION_TAG = 76, HTT_STATS_RX_REFILL_RXDMA_ERR_TAG = 77, HTT_STATS_RX_REFILL_REO_ERR_TAG = 78, HTT_STATS_RX_REO_RESOURCE_STATS_TAG = 79, HTT_STATS_TX_SOUNDING_STATS_TAG = 80, HTT_STATS_TX_PDEV_TX_PPDU_STATS_TAG = 81, HTT_STATS_TX_PDEV_TRIED_MPDU_CNT_HIST_TAG = 82, HTT_STATS_TX_HWQ_TRIED_MPDU_CNT_HIST_TAG = 83, HTT_STATS_TX_HWQ_TXOP_USED_CNT_HIST_TAG = 84, HTT_STATS_TX_DE_FW2WBM_RING_FULL_HIST_TAG = 85, HTT_STATS_SCHED_TXQ_SCHED_ORDER_SU_TAG = 86, HTT_STATS_SCHED_TXQ_SCHED_INELIGIBILITY_TAG = 87, HTT_STATS_PDEV_OBSS_PD_TAG = 88, HTT_STATS_HW_WAR_TAG = 89, HTT_STATS_RING_BACKPRESSURE_STATS_TAG = 90, HTT_STATS_MAX_TAG, }; #define HTT_STATS_MAX_STRING_SZ32 4 #define HTT_STATS_MACID_INVALID 0xff #define HTT_TX_HWQ_MAX_DIFS_LATENCY_BINS 10 #define HTT_TX_HWQ_MAX_CMD_RESULT_STATS 13 #define HTT_TX_HWQ_MAX_CMD_STALL_STATS 5 #define HTT_TX_HWQ_MAX_FES_RESULT_STATS 10 enum htt_tx_pdev_underrun_enum { HTT_STATS_TX_PDEV_NO_DATA_UNDERRUN = 0, HTT_STATS_TX_PDEV_DATA_UNDERRUN_BETWEEN_MPDU = 1, HTT_STATS_TX_PDEV_DATA_UNDERRUN_WITHIN_MPDU = 2, HTT_TX_PDEV_MAX_URRN_STATS = 3, }; #define HTT_TX_PDEV_MAX_FLUSH_REASON_STATS 71 #define HTT_TX_PDEV_MAX_SIFS_BURST_STATS 9 #define HTT_TX_PDEV_MAX_SIFS_BURST_HIST_STATS 10 #define HTT_TX_PDEV_MAX_PHY_ERR_STATS 18 #define HTT_TX_PDEV_SCHED_TX_MODE_MAX 4 #define HTT_TX_PDEV_NUM_SCHED_ORDER_LOG 20 #define HTT_RX_STATS_REFILL_MAX_RING 4 #define HTT_RX_STATS_RXDMA_MAX_ERR 16 #define HTT_RX_STATS_FW_DROP_REASON_MAX 16 /* Bytes stored in little endian order */ /* Length should be multiple of DWORD */ struct htt_stats_string_tlv { u32 data[0]; /* Can be variable length */ } __packed; /* == TX PDEV STATS == */ struct htt_tx_pdev_stats_cmn_tlv { u32 mac_id__word; u32 hw_queued; u32 hw_reaped; u32 underrun; u32 hw_paused; u32 hw_flush; u32 hw_filt; u32 tx_abort; u32 mpdu_requed; u32 tx_xretry; u32 data_rc; u32 mpdu_dropped_xretry; u32 illgl_rate_phy_err; u32 cont_xretry; u32 tx_timeout; u32 pdev_resets; u32 phy_underrun; u32 txop_ovf; u32 seq_posted; u32 seq_failed_queueing; u32 seq_completed; u32 seq_restarted; u32 mu_seq_posted; u32 seq_switch_hw_paused; u32 next_seq_posted_dsr; u32 seq_posted_isr; u32 seq_ctrl_cached; u32 mpdu_count_tqm; u32 msdu_count_tqm; u32 mpdu_removed_tqm; u32 msdu_removed_tqm; u32 mpdus_sw_flush; u32 mpdus_hw_filter; u32 mpdus_truncated; u32 mpdus_ack_failed; u32 mpdus_expired; u32 mpdus_seq_hw_retry; u32 ack_tlv_proc; u32 coex_abort_mpdu_cnt_valid; u32 coex_abort_mpdu_cnt; u32 num_total_ppdus_tried_ota; u32 num_data_ppdus_tried_ota; u32 local_ctrl_mgmt_enqued; u32 local_ctrl_mgmt_freed; u32 local_data_enqued; u32 local_data_freed; u32 mpdu_tried; u32 isr_wait_seq_posted; u32 tx_active_dur_us_low; u32 tx_active_dur_us_high; }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_pdev_stats_urrn_tlv_v { u32 urrn_stats[0]; /* HTT_TX_PDEV_MAX_URRN_STATS */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_pdev_stats_flush_tlv_v { u32 flush_errs[0]; /* HTT_TX_PDEV_MAX_FLUSH_REASON_STATS */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_pdev_stats_sifs_tlv_v { u32 sifs_status[0]; /* HTT_TX_PDEV_MAX_SIFS_BURST_STATS */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_pdev_stats_phy_err_tlv_v { u32 phy_errs[0]; /* HTT_TX_PDEV_MAX_PHY_ERR_STATS */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_pdev_stats_sifs_hist_tlv_v { u32 sifs_hist_status[0]; /* HTT_TX_PDEV_SIFS_BURST_HIST_STATS */ }; struct htt_tx_pdev_stats_tx_ppdu_stats_tlv_v { u32 num_data_ppdus_legacy_su; u32 num_data_ppdus_ac_su; u32 num_data_ppdus_ax_su; u32 num_data_ppdus_ac_su_txbf; u32 num_data_ppdus_ax_su_txbf; }; /* NOTE: Variable length TLV, use length spec to infer array size . * * Tried_mpdu_cnt_hist is the histogram of MPDUs tries per HWQ. * The tries here is the count of the MPDUS within a PPDU that the * HW had attempted to transmit on air, for the HWSCH Schedule * command submitted by FW.It is not the retry attempts. * The histogram bins are 0-29, 30-59, 60-89 and so on. The are * 10 bins in this histogram. They are defined in FW using the * following macros * #define WAL_MAX_TRIED_MPDU_CNT_HISTOGRAM 9 * #define WAL_TRIED_MPDU_CNT_HISTOGRAM_INTERVAL 30 */ struct htt_tx_pdev_stats_tried_mpdu_cnt_hist_tlv_v { u32 hist_bin_size; u32 tried_mpdu_cnt_hist[]; /* HTT_TX_PDEV_TRIED_MPDU_CNT_HIST */ }; /* == SOC ERROR STATS == */ /* =============== PDEV ERROR STATS ============== */ #define HTT_STATS_MAX_HW_INTR_NAME_LEN 8 struct htt_hw_stats_intr_misc_tlv { /* Stored as little endian */ u8 hw_intr_name[HTT_STATS_MAX_HW_INTR_NAME_LEN]; u32 mask; u32 count; }; #define HTT_STATS_MAX_HW_MODULE_NAME_LEN 8 struct htt_hw_stats_wd_timeout_tlv { /* Stored as little endian */ u8 hw_module_name[HTT_STATS_MAX_HW_MODULE_NAME_LEN]; u32 count; }; struct htt_hw_stats_pdev_errs_tlv { u32 mac_id__word; /* BIT [ 7 : 0] : mac_id */ u32 tx_abort; u32 tx_abort_fail_count; u32 rx_abort; u32 rx_abort_fail_count; u32 warm_reset; u32 cold_reset; u32 tx_flush; u32 tx_glb_reset; u32 tx_txq_reset; u32 rx_timeout_reset; }; struct htt_hw_stats_whal_tx_tlv { u32 mac_id__word; u32 last_unpause_ppdu_id; u32 hwsch_unpause_wait_tqm_write; u32 hwsch_dummy_tlv_skipped; u32 hwsch_misaligned_offset_received; u32 hwsch_reset_count; u32 hwsch_dev_reset_war; u32 hwsch_delayed_pause; u32 hwsch_long_delayed_pause; u32 sch_rx_ppdu_no_response; u32 sch_selfgen_response; u32 sch_rx_sifs_resp_trigger; }; /* ============ PEER STATS ============ */ struct htt_msdu_flow_stats_tlv { u32 last_update_timestamp; u32 last_add_timestamp; u32 last_remove_timestamp; u32 total_processed_msdu_count; u32 cur_msdu_count_in_flowq; u32 sw_peer_id; u32 tx_flow_no__tid_num__drop_rule; u32 last_cycle_enqueue_count; u32 last_cycle_dequeue_count; u32 last_cycle_drop_count; u32 current_drop_th; }; #define MAX_HTT_TID_NAME 8 /* Tidq stats */ struct htt_tx_tid_stats_tlv { /* Stored as little endian */ u8 tid_name[MAX_HTT_TID_NAME]; u32 sw_peer_id__tid_num; u32 num_sched_pending__num_ppdu_in_hwq; u32 tid_flags; u32 hw_queued; u32 hw_reaped; u32 mpdus_hw_filter; u32 qdepth_bytes; u32 qdepth_num_msdu; u32 qdepth_num_mpdu; u32 last_scheduled_tsmp; u32 pause_module_id; u32 block_module_id; u32 tid_tx_airtime; }; /* Tidq stats */ struct htt_tx_tid_stats_v1_tlv { /* Stored as little endian */ u8 tid_name[MAX_HTT_TID_NAME]; u32 sw_peer_id__tid_num; u32 num_sched_pending__num_ppdu_in_hwq; u32 tid_flags; u32 max_qdepth_bytes; u32 max_qdepth_n_msdus; u32 rsvd; u32 qdepth_bytes; u32 qdepth_num_msdu; u32 qdepth_num_mpdu; u32 last_scheduled_tsmp; u32 pause_module_id; u32 block_module_id; u32 tid_tx_airtime; u32 allow_n_flags; u32 sendn_frms_allowed; }; struct htt_rx_tid_stats_tlv { u32 sw_peer_id__tid_num; u8 tid_name[MAX_HTT_TID_NAME]; u32 dup_in_reorder; u32 dup_past_outside_window; u32 dup_past_within_window; u32 rxdesc_err_decrypt; u32 tid_rx_airtime; }; #define HTT_MAX_COUNTER_NAME 8 struct htt_counter_tlv { u8 counter_name[HTT_MAX_COUNTER_NAME]; u32 count; }; struct htt_peer_stats_cmn_tlv { u32 ppdu_cnt; u32 mpdu_cnt; u32 msdu_cnt; u32 pause_bitmap; u32 block_bitmap; u32 current_timestamp; u32 peer_tx_airtime; u32 peer_rx_airtime; s32 rssi; u32 peer_enqueued_count_low; u32 peer_enqueued_count_high; u32 peer_dequeued_count_low; u32 peer_dequeued_count_high; u32 peer_dropped_count_low; u32 peer_dropped_count_high; u32 ppdu_transmitted_bytes_low; u32 ppdu_transmitted_bytes_high; u32 peer_ttl_removed_count; u32 inactive_time; }; struct htt_peer_details_tlv { u32 peer_type; u32 sw_peer_id; u32 vdev_pdev_ast_idx; struct htt_mac_addr mac_addr; u32 peer_flags; u32 qpeer_flags; }; enum htt_stats_param_type { HTT_STATS_PREAM_OFDM, HTT_STATS_PREAM_CCK, HTT_STATS_PREAM_HT, HTT_STATS_PREAM_VHT, HTT_STATS_PREAM_HE, HTT_STATS_PREAM_RSVD, HTT_STATS_PREAM_RSVD1, HTT_STATS_PREAM_COUNT, }; #define HTT_TX_PEER_STATS_NUM_MCS_COUNTERS 12 #define HTT_TX_PEER_STATS_NUM_GI_COUNTERS 4 #define HTT_TX_PEER_STATS_NUM_DCM_COUNTERS 5 #define HTT_TX_PEER_STATS_NUM_BW_COUNTERS 4 #define HTT_TX_PEER_STATS_NUM_SPATIAL_STREAMS 8 #define HTT_TX_PEER_STATS_NUM_PREAMBLE_TYPES HTT_STATS_PREAM_COUNT struct htt_tx_peer_rate_stats_tlv { u32 tx_ldpc; u32 rts_cnt; u32 ack_rssi; u32 tx_mcs[HTT_TX_PEER_STATS_NUM_MCS_COUNTERS]; u32 tx_su_mcs[HTT_TX_PEER_STATS_NUM_MCS_COUNTERS]; u32 tx_mu_mcs[HTT_TX_PEER_STATS_NUM_MCS_COUNTERS]; /* element 0,1, ...7 -> NSS 1,2, ...8 */ u32 tx_nss[HTT_TX_PEER_STATS_NUM_SPATIAL_STREAMS]; /* element 0: 20 MHz, 1: 40 MHz, 2: 80 MHz, 3: 160 and 80+80 MHz */ u32 tx_bw[HTT_TX_PEER_STATS_NUM_BW_COUNTERS]; u32 tx_stbc[HTT_TX_PEER_STATS_NUM_MCS_COUNTERS]; u32 tx_pream[HTT_TX_PEER_STATS_NUM_PREAMBLE_TYPES]; /* Counters to track number of tx packets in each GI * (400us, 800us, 1600us & 3200us) in each mcs (0-11) */ u32 tx_gi[HTT_TX_PEER_STATS_NUM_GI_COUNTERS][HTT_TX_PEER_STATS_NUM_MCS_COUNTERS]; /* Counters to track packets in dcm mcs (MCS 0, 1, 3, 4) */ u32 tx_dcm[HTT_TX_PEER_STATS_NUM_DCM_COUNTERS]; }; #define HTT_RX_PEER_STATS_NUM_MCS_COUNTERS 12 #define HTT_RX_PEER_STATS_NUM_GI_COUNTERS 4 #define HTT_RX_PEER_STATS_NUM_DCM_COUNTERS 5 #define HTT_RX_PEER_STATS_NUM_BW_COUNTERS 4 #define HTT_RX_PEER_STATS_NUM_SPATIAL_STREAMS 8 #define HTT_RX_PEER_STATS_NUM_PREAMBLE_TYPES HTT_STATS_PREAM_COUNT struct htt_rx_peer_rate_stats_tlv { u32 nsts; /* Number of rx ldpc packets */ u32 rx_ldpc; /* Number of rx rts packets */ u32 rts_cnt; u32 rssi_mgmt; /* units = dB above noise floor */ u32 rssi_data; /* units = dB above noise floor */ u32 rssi_comb; /* units = dB above noise floor */ u32 rx_mcs[HTT_RX_PEER_STATS_NUM_MCS_COUNTERS]; /* element 0,1, ...7 -> NSS 1,2, ...8 */ u32 rx_nss[HTT_RX_PEER_STATS_NUM_SPATIAL_STREAMS]; u32 rx_dcm[HTT_RX_PEER_STATS_NUM_DCM_COUNTERS]; u32 rx_stbc[HTT_RX_PEER_STATS_NUM_MCS_COUNTERS]; /* element 0: 20 MHz, 1: 40 MHz, 2: 80 MHz, 3: 160 and 80+80 MHz */ u32 rx_bw[HTT_RX_PEER_STATS_NUM_BW_COUNTERS]; u32 rx_pream[HTT_RX_PEER_STATS_NUM_PREAMBLE_TYPES]; /* units = dB above noise floor */ u8 rssi_chain[HTT_RX_PEER_STATS_NUM_SPATIAL_STREAMS] [HTT_RX_PEER_STATS_NUM_BW_COUNTERS]; /* Counters to track number of rx packets in each GI in each mcs (0-11) */ u32 rx_gi[HTT_RX_PEER_STATS_NUM_GI_COUNTERS] [HTT_RX_PEER_STATS_NUM_MCS_COUNTERS]; }; enum htt_peer_stats_req_mode { HTT_PEER_STATS_REQ_MODE_NO_QUERY, HTT_PEER_STATS_REQ_MODE_QUERY_TQM, HTT_PEER_STATS_REQ_MODE_FLUSH_TQM, }; enum htt_peer_stats_tlv_enum { HTT_PEER_STATS_CMN_TLV = 0, HTT_PEER_DETAILS_TLV = 1, HTT_TX_PEER_RATE_STATS_TLV = 2, HTT_RX_PEER_RATE_STATS_TLV = 3, HTT_TX_TID_STATS_TLV = 4, HTT_RX_TID_STATS_TLV = 5, HTT_MSDU_FLOW_STATS_TLV = 6, HTT_PEER_STATS_MAX_TLV = 31, }; /* =========== MUMIMO HWQ stats =========== */ /* MU MIMO stats per hwQ */ struct htt_tx_hwq_mu_mimo_sch_stats_tlv { u32 mu_mimo_sch_posted; u32 mu_mimo_sch_failed; u32 mu_mimo_ppdu_posted; }; struct htt_tx_hwq_mu_mimo_mpdu_stats_tlv { u32 mu_mimo_mpdus_queued_usr; u32 mu_mimo_mpdus_tried_usr; u32 mu_mimo_mpdus_failed_usr; u32 mu_mimo_mpdus_requeued_usr; u32 mu_mimo_err_no_ba_usr; u32 mu_mimo_mpdu_underrun_usr; u32 mu_mimo_ampdu_underrun_usr; }; struct htt_tx_hwq_mu_mimo_cmn_stats_tlv { u32 mac_id__hwq_id__word; }; /* == TX HWQ STATS == */ struct htt_tx_hwq_stats_cmn_tlv { u32 mac_id__hwq_id__word; /* PPDU level stats */ u32 xretry; u32 underrun_cnt; u32 flush_cnt; u32 filt_cnt; u32 null_mpdu_bmap; u32 user_ack_failure; u32 ack_tlv_proc; u32 sched_id_proc; u32 null_mpdu_tx_count; u32 mpdu_bmap_not_recvd; /* Selfgen stats per hwQ */ u32 num_bar; u32 rts; u32 cts2self; u32 qos_null; /* MPDU level stats */ u32 mpdu_tried_cnt; u32 mpdu_queued_cnt; u32 mpdu_ack_fail_cnt; u32 mpdu_filt_cnt; u32 false_mpdu_ack_count; u32 txq_timeout; }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_hwq_difs_latency_stats_tlv_v { u32 hist_intvl; /* histogram of ppdu post to hwsch - > cmd status received */ u32 difs_latency_hist[]; /* HTT_TX_HWQ_MAX_DIFS_LATENCY_BINS */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_hwq_cmd_result_stats_tlv_v { /* Histogram of sched cmd result */ u32 cmd_result[0]; /* HTT_TX_HWQ_MAX_CMD_RESULT_STATS */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_hwq_cmd_stall_stats_tlv_v { /* Histogram of various pause conitions */ u32 cmd_stall_status[0]; /* HTT_TX_HWQ_MAX_CMD_STALL_STATS */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_hwq_fes_result_stats_tlv_v { /* Histogram of number of user fes result */ u32 fes_result[0]; /* HTT_TX_HWQ_MAX_FES_RESULT_STATS */ }; /* NOTE: Variable length TLV, use length spec to infer array size * * The hwq_tried_mpdu_cnt_hist is a histogram of MPDUs tries per HWQ. * The tries here is the count of the MPDUS within a PPDU that the HW * had attempted to transmit on air, for the HWSCH Schedule command * submitted by FW in this HWQ .It is not the retry attempts. The * histogram bins are 0-29, 30-59, 60-89 and so on. The are 10 bins * in this histogram. * they are defined in FW using the following macros * #define WAL_MAX_TRIED_MPDU_CNT_HISTOGRAM 9 * #define WAL_TRIED_MPDU_CNT_HISTOGRAM_INTERVAL 30 */ struct htt_tx_hwq_tried_mpdu_cnt_hist_tlv_v { u32 hist_bin_size; /* Histogram of number of mpdus on tried mpdu */ u32 tried_mpdu_cnt_hist[]; /* HTT_TX_HWQ_TRIED_MPDU_CNT_HIST */ }; /* NOTE: Variable length TLV, use length spec to infer array size * * The txop_used_cnt_hist is the histogram of txop per burst. After * completing the burst, we identify the txop used in the burst and * incr the corresponding bin. * Each bin represents 1ms & we have 10 bins in this histogram. * they are deined in FW using the following macros * #define WAL_MAX_TXOP_USED_CNT_HISTOGRAM 10 * #define WAL_TXOP_USED_HISTOGRAM_INTERVAL 1000 ( 1 ms ) */ struct htt_tx_hwq_txop_used_cnt_hist_tlv_v { /* Histogram of txop used cnt */ u32 txop_used_cnt_hist[0]; /* HTT_TX_HWQ_TXOP_USED_CNT_HIST */ }; /* == TX SELFGEN STATS == */ struct htt_tx_selfgen_cmn_stats_tlv { u32 mac_id__word; u32 su_bar; u32 rts; u32 cts2self; u32 qos_null; u32 delayed_bar_1; /* MU user 1 */ u32 delayed_bar_2; /* MU user 2 */ u32 delayed_bar_3; /* MU user 3 */ u32 delayed_bar_4; /* MU user 4 */ u32 delayed_bar_5; /* MU user 5 */ u32 delayed_bar_6; /* MU user 6 */ u32 delayed_bar_7; /* MU user 7 */ }; struct htt_tx_selfgen_ac_stats_tlv { /* 11AC */ u32 ac_su_ndpa; u32 ac_su_ndp; u32 ac_mu_mimo_ndpa; u32 ac_mu_mimo_ndp; u32 ac_mu_mimo_brpoll_1; /* MU user 1 */ u32 ac_mu_mimo_brpoll_2; /* MU user 2 */ u32 ac_mu_mimo_brpoll_3; /* MU user 3 */ }; struct htt_tx_selfgen_ax_stats_tlv { /* 11AX */ u32 ax_su_ndpa; u32 ax_su_ndp; u32 ax_mu_mimo_ndpa; u32 ax_mu_mimo_ndp; u32 ax_mu_mimo_brpoll_1; /* MU user 1 */ u32 ax_mu_mimo_brpoll_2; /* MU user 2 */ u32 ax_mu_mimo_brpoll_3; /* MU user 3 */ u32 ax_mu_mimo_brpoll_4; /* MU user 4 */ u32 ax_mu_mimo_brpoll_5; /* MU user 5 */ u32 ax_mu_mimo_brpoll_6; /* MU user 6 */ u32 ax_mu_mimo_brpoll_7; /* MU user 7 */ u32 ax_basic_trigger; u32 ax_bsr_trigger; u32 ax_mu_bar_trigger; u32 ax_mu_rts_trigger; }; struct htt_tx_selfgen_ac_err_stats_tlv { /* 11AC error stats */ u32 ac_su_ndp_err; u32 ac_su_ndpa_err; u32 ac_mu_mimo_ndpa_err; u32 ac_mu_mimo_ndp_err; u32 ac_mu_mimo_brp1_err; u32 ac_mu_mimo_brp2_err; u32 ac_mu_mimo_brp3_err; }; struct htt_tx_selfgen_ax_err_stats_tlv { /* 11AX error stats */ u32 ax_su_ndp_err; u32 ax_su_ndpa_err; u32 ax_mu_mimo_ndpa_err; u32 ax_mu_mimo_ndp_err; u32 ax_mu_mimo_brp1_err; u32 ax_mu_mimo_brp2_err; u32 ax_mu_mimo_brp3_err; u32 ax_mu_mimo_brp4_err; u32 ax_mu_mimo_brp5_err; u32 ax_mu_mimo_brp6_err; u32 ax_mu_mimo_brp7_err; u32 ax_basic_trigger_err; u32 ax_bsr_trigger_err; u32 ax_mu_bar_trigger_err; u32 ax_mu_rts_trigger_err; }; /* == TX MU STATS == */ #define HTT_TX_PDEV_STATS_NUM_AC_MUMIMO_USER_STATS 4 #define HTT_TX_PDEV_STATS_NUM_AX_MUMIMO_USER_STATS 8 #define HTT_TX_PDEV_STATS_NUM_OFDMA_USER_STATS 74 struct htt_tx_pdev_mu_mimo_sch_stats_tlv { /* mu-mimo sw sched cmd stats */ u32 mu_mimo_sch_posted; u32 mu_mimo_sch_failed; /* MU PPDU stats per hwQ */ u32 mu_mimo_ppdu_posted; /* * Counts the number of users in each transmission of * the given TX mode. * * Index is the number of users - 1. */ u32 ac_mu_mimo_sch_nusers[HTT_TX_PDEV_STATS_NUM_AC_MUMIMO_USER_STATS]; u32 ax_mu_mimo_sch_nusers[HTT_TX_PDEV_STATS_NUM_AX_MUMIMO_USER_STATS]; u32 ax_ofdma_sch_nusers[HTT_TX_PDEV_STATS_NUM_OFDMA_USER_STATS]; }; struct htt_tx_pdev_mu_mimo_mpdu_stats_tlv { u32 mu_mimo_mpdus_queued_usr; u32 mu_mimo_mpdus_tried_usr; u32 mu_mimo_mpdus_failed_usr; u32 mu_mimo_mpdus_requeued_usr; u32 mu_mimo_err_no_ba_usr; u32 mu_mimo_mpdu_underrun_usr; u32 mu_mimo_ampdu_underrun_usr; u32 ax_mu_mimo_mpdus_queued_usr; u32 ax_mu_mimo_mpdus_tried_usr; u32 ax_mu_mimo_mpdus_failed_usr; u32 ax_mu_mimo_mpdus_requeued_usr; u32 ax_mu_mimo_err_no_ba_usr; u32 ax_mu_mimo_mpdu_underrun_usr; u32 ax_mu_mimo_ampdu_underrun_usr; u32 ax_ofdma_mpdus_queued_usr; u32 ax_ofdma_mpdus_tried_usr; u32 ax_ofdma_mpdus_failed_usr; u32 ax_ofdma_mpdus_requeued_usr; u32 ax_ofdma_err_no_ba_usr; u32 ax_ofdma_mpdu_underrun_usr; u32 ax_ofdma_ampdu_underrun_usr; }; #define HTT_STATS_TX_SCHED_MODE_MU_MIMO_AC 1 #define HTT_STATS_TX_SCHED_MODE_MU_MIMO_AX 2 #define HTT_STATS_TX_SCHED_MODE_MU_OFDMA_AX 3 struct htt_tx_pdev_mpdu_stats_tlv { /* mpdu level stats */ u32 mpdus_queued_usr; u32 mpdus_tried_usr; u32 mpdus_failed_usr; u32 mpdus_requeued_usr; u32 err_no_ba_usr; u32 mpdu_underrun_usr; u32 ampdu_underrun_usr; u32 user_index; u32 tx_sched_mode; /* HTT_STATS_TX_SCHED_MODE_xxx */ }; /* == TX SCHED STATS == */ /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_sched_txq_cmd_posted_tlv_v { u32 sched_cmd_posted[0]; /* HTT_TX_PDEV_SCHED_TX_MODE_MAX */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_sched_txq_cmd_reaped_tlv_v { u32 sched_cmd_reaped[0]; /* HTT_TX_PDEV_SCHED_TX_MODE_MAX */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_sched_txq_sched_order_su_tlv_v { u32 sched_order_su[0]; /* HTT_TX_PDEV_NUM_SCHED_ORDER_LOG */ }; enum htt_sched_txq_sched_ineligibility_tlv_enum { HTT_SCHED_TID_SKIP_SCHED_MASK_DISABLED = 0, HTT_SCHED_TID_SKIP_NOTIFY_MPDU, HTT_SCHED_TID_SKIP_MPDU_STATE_INVALID, HTT_SCHED_TID_SKIP_SCHED_DISABLED, HTT_SCHED_TID_SKIP_TQM_BYPASS_CMD_PENDING, HTT_SCHED_TID_SKIP_SECOND_SU_SCHEDULE, HTT_SCHED_TID_SKIP_CMD_SLOT_NOT_AVAIL, HTT_SCHED_TID_SKIP_NO_ENQ, HTT_SCHED_TID_SKIP_LOW_ENQ, HTT_SCHED_TID_SKIP_PAUSED, HTT_SCHED_TID_SKIP_UL, HTT_SCHED_TID_REMOVE_PAUSED, HTT_SCHED_TID_REMOVE_NO_ENQ, HTT_SCHED_TID_REMOVE_UL, HTT_SCHED_TID_QUERY, HTT_SCHED_TID_SU_ONLY, HTT_SCHED_TID_ELIGIBLE, HTT_SCHED_INELIGIBILITY_MAX, }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_sched_txq_sched_ineligibility_tlv_v { /* indexed by htt_sched_txq_sched_ineligibility_tlv_enum */ u32 sched_ineligibility[0]; }; struct htt_tx_pdev_stats_sched_per_txq_tlv { u32 mac_id__txq_id__word; u32 sched_policy; u32 last_sched_cmd_posted_timestamp; u32 last_sched_cmd_compl_timestamp; u32 sched_2_tac_lwm_count; u32 sched_2_tac_ring_full; u32 sched_cmd_post_failure; u32 num_active_tids; u32 num_ps_schedules; u32 sched_cmds_pending; u32 num_tid_register; u32 num_tid_unregister; u32 num_qstats_queried; u32 qstats_update_pending; u32 last_qstats_query_timestamp; u32 num_tqm_cmdq_full; u32 num_de_sched_algo_trigger; u32 num_rt_sched_algo_trigger; u32 num_tqm_sched_algo_trigger; u32 notify_sched; u32 dur_based_sendn_term; }; struct htt_stats_tx_sched_cmn_tlv { /* BIT [ 7 : 0] :- mac_id * BIT [31 : 8] :- reserved */ u32 mac_id__word; /* Current timestamp */ u32 current_timestamp; }; /* == TQM STATS == */ #define HTT_TX_TQM_MAX_GEN_MPDU_END_REASON 16 #define HTT_TX_TQM_MAX_LIST_MPDU_END_REASON 16 #define HTT_TX_TQM_MAX_LIST_MPDU_CNT_HISTOGRAM_BINS 16 /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_tqm_gen_mpdu_stats_tlv_v { u32 gen_mpdu_end_reason[0]; /* HTT_TX_TQM_MAX_GEN_MPDU_END_REASON */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_tqm_list_mpdu_stats_tlv_v { u32 list_mpdu_end_reason[0]; /* HTT_TX_TQM_MAX_LIST_MPDU_END_REASON */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_tx_tqm_list_mpdu_cnt_tlv_v { u32 list_mpdu_cnt_hist[0]; /* HTT_TX_TQM_MAX_LIST_MPDU_CNT_HISTOGRAM_BINS */ }; struct htt_tx_tqm_pdev_stats_tlv_v { u32 msdu_count; u32 mpdu_count; u32 remove_msdu; u32 remove_mpdu; u32 remove_msdu_ttl; u32 send_bar; u32 bar_sync; u32 notify_mpdu; u32 sync_cmd; u32 write_cmd; u32 hwsch_trigger; u32 ack_tlv_proc; u32 gen_mpdu_cmd; u32 gen_list_cmd; u32 remove_mpdu_cmd; u32 remove_mpdu_tried_cmd; u32 mpdu_queue_stats_cmd; u32 mpdu_head_info_cmd; u32 msdu_flow_stats_cmd; u32 remove_msdu_cmd; u32 remove_msdu_ttl_cmd; u32 flush_cache_cmd; u32 update_mpduq_cmd; u32 enqueue; u32 enqueue_notify; u32 notify_mpdu_at_head; u32 notify_mpdu_state_valid; /* * On receiving TQM_FLOW_NOT_EMPTY_STATUS from TQM, (on MSDUs being enqueued * the flow is non empty), if the number of MSDUs is greater than the threshold, * notify is incremented. UDP_THRESH counters are for UDP MSDUs, and NONUDP are * for non-UDP MSDUs. * MSDUQ_SWNOTIFY_UDP_THRESH1 threshold - sched_udp_notify1 is incremented * MSDUQ_SWNOTIFY_UDP_THRESH2 threshold - sched_udp_notify2 is incremented * MSDUQ_SWNOTIFY_NONUDP_THRESH1 threshold - sched_nonudp_notify1 is incremented * MSDUQ_SWNOTIFY_NONUDP_THRESH2 threshold - sched_nonudp_notify2 is incremented * * Notify signifies that we trigger the scheduler. */ u32 sched_udp_notify1; u32 sched_udp_notify2; u32 sched_nonudp_notify1; u32 sched_nonudp_notify2; }; struct htt_tx_tqm_cmn_stats_tlv { u32 mac_id__word; u32 max_cmdq_id; u32 list_mpdu_cnt_hist_intvl; /* Global stats */ u32 add_msdu; u32 q_empty; u32 q_not_empty; u32 drop_notification; u32 desc_threshold; }; struct htt_tx_tqm_error_stats_tlv { /* Error stats */ u32 q_empty_failure; u32 q_not_empty_failure; u32 add_msdu_failure; }; /* == TQM CMDQ stats == */ struct htt_tx_tqm_cmdq_status_tlv { u32 mac_id__cmdq_id__word; u32 sync_cmd; u32 write_cmd; u32 gen_mpdu_cmd; u32 mpdu_queue_stats_cmd; u32 mpdu_head_info_cmd; u32 msdu_flow_stats_cmd; u32 remove_mpdu_cmd; u32 remove_msdu_cmd; u32 flush_cache_cmd; u32 update_mpduq_cmd; u32 update_msduq_cmd; }; /* == TX-DE STATS == */ /* Structures for tx de stats */ struct htt_tx_de_eapol_packets_stats_tlv { u32 m1_packets; u32 m2_packets; u32 m3_packets; u32 m4_packets; u32 g1_packets; u32 g2_packets; }; struct htt_tx_de_classify_failed_stats_tlv { u32 ap_bss_peer_not_found; u32 ap_bcast_mcast_no_peer; u32 sta_delete_in_progress; u32 ibss_no_bss_peer; u32 invalid_vdev_type; u32 invalid_ast_peer_entry; u32 peer_entry_invalid; u32 ethertype_not_ip; u32 eapol_lookup_failed; u32 qpeer_not_allow_data; u32 fse_tid_override; u32 ipv6_jumbogram_zero_length; u32 qos_to_non_qos_in_prog; }; struct htt_tx_de_classify_stats_tlv { u32 arp_packets; u32 igmp_packets; u32 dhcp_packets; u32 host_inspected; u32 htt_included; u32 htt_valid_mcs; u32 htt_valid_nss; u32 htt_valid_preamble_type; u32 htt_valid_chainmask; u32 htt_valid_guard_interval; u32 htt_valid_retries; u32 htt_valid_bw_info; u32 htt_valid_power; u32 htt_valid_key_flags; u32 htt_valid_no_encryption; u32 fse_entry_count; u32 fse_priority_be; u32 fse_priority_high; u32 fse_priority_low; u32 fse_traffic_ptrn_be; u32 fse_traffic_ptrn_over_sub; u32 fse_traffic_ptrn_bursty; u32 fse_traffic_ptrn_interactive; u32 fse_traffic_ptrn_periodic; u32 fse_hwqueue_alloc; u32 fse_hwqueue_created; u32 fse_hwqueue_send_to_host; u32 mcast_entry; u32 bcast_entry; u32 htt_update_peer_cache; u32 htt_learning_frame; u32 fse_invalid_peer; /* * mec_notify is HTT TX WBM multicast echo check notification * from firmware to host. FW sends SA addresses to host for all * multicast/broadcast packets received on STA side. */ u32 mec_notify; }; struct htt_tx_de_classify_status_stats_tlv { u32 eok; u32 classify_done; u32 lookup_failed; u32 send_host_dhcp; u32 send_host_mcast; u32 send_host_unknown_dest; u32 send_host; u32 status_invalid; }; struct htt_tx_de_enqueue_packets_stats_tlv { u32 enqueued_pkts; u32 to_tqm; u32 to_tqm_bypass; }; struct htt_tx_de_enqueue_discard_stats_tlv { u32 discarded_pkts; u32 local_frames; u32 is_ext_msdu; }; struct htt_tx_de_compl_stats_tlv { u32 tcl_dummy_frame; u32 tqm_dummy_frame; u32 tqm_notify_frame; u32 fw2wbm_enq; u32 tqm_bypass_frame; }; /* * The htt_tx_de_fw2wbm_ring_full_hist_tlv is a histogram of time we waited * for the fw2wbm ring buffer. we are requesting a buffer in FW2WBM release * ring,which may fail, due to non availability of buffer. Hence we sleep for * 200us & again request for it. This is a histogram of time we wait, with * bin of 200ms & there are 10 bin (2 seconds max) * They are defined by the following macros in FW * #define ENTRIES_PER_BIN_COUNT 1000 // per bin 1000 * 200us = 200ms * #define RING_FULL_BIN_ENTRIES (WAL_TX_DE_FW2WBM_ALLOC_TIMEOUT_COUNT / * ENTRIES_PER_BIN_COUNT) */ struct htt_tx_de_fw2wbm_ring_full_hist_tlv { u32 fw2wbm_ring_full_hist[0]; }; struct htt_tx_de_cmn_stats_tlv { u32 mac_id__word; /* Global Stats */ u32 tcl2fw_entry_count; u32 not_to_fw; u32 invalid_pdev_vdev_peer; u32 tcl_res_invalid_addrx; u32 wbm2fw_entry_count; u32 invalid_pdev; }; /* == RING-IF STATS == */ #define HTT_STATS_LOW_WM_BINS 5 #define HTT_STATS_HIGH_WM_BINS 5 struct htt_ring_if_stats_tlv { u32 base_addr; /* DWORD aligned base memory address of the ring */ u32 elem_size; u32 num_elems__prefetch_tail_idx; u32 head_idx__tail_idx; u32 shadow_head_idx__shadow_tail_idx; u32 num_tail_incr; u32 lwm_thresh__hwm_thresh; u32 overrun_hit_count; u32 underrun_hit_count; u32 prod_blockwait_count; u32 cons_blockwait_count; u32 low_wm_hit_count[HTT_STATS_LOW_WM_BINS]; u32 high_wm_hit_count[HTT_STATS_HIGH_WM_BINS]; }; struct htt_ring_if_cmn_tlv { u32 mac_id__word; u32 num_records; }; /* == SFM STATS == */ /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_sfm_client_user_tlv_v { /* Number of DWORDS used per user and per client */ u32 dwords_used_by_user_n[0]; }; struct htt_sfm_client_tlv { /* Client ID */ u32 client_id; /* Minimum number of buffers */ u32 buf_min; /* Maximum number of buffers */ u32 buf_max; /* Number of Busy buffers */ u32 buf_busy; /* Number of Allocated buffers */ u32 buf_alloc; /* Number of Available/Usable buffers */ u32 buf_avail; /* Number of users */ u32 num_users; }; struct htt_sfm_cmn_tlv { u32 mac_id__word; /* Indicates the total number of 128 byte buffers * in the CMEM that are available for buffer sharing */ u32 buf_total; /* Indicates for certain client or all the clients * there is no dowrd saved in SFM, refer to SFM_R1_MEM_EMPTY */ u32 mem_empty; /* DEALLOCATE_BUFFERS, refer to register SFM_R0_DEALLOCATE_BUFFERS */ u32 deallocate_bufs; /* Number of Records */ u32 num_records; }; /* == SRNG STATS == */ struct htt_sring_stats_tlv { u32 mac_id__ring_id__arena__ep; u32 base_addr_lsb; /* DWORD aligned base memory address of the ring */ u32 base_addr_msb; u32 ring_size; u32 elem_size; u32 num_avail_words__num_valid_words; u32 head_ptr__tail_ptr; u32 consumer_empty__producer_full; u32 prefetch_count__internal_tail_ptr; }; struct htt_sring_cmn_tlv { u32 num_records; }; /* == PDEV TX RATE CTRL STATS == */ #define HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS 12 #define HTT_TX_PDEV_STATS_NUM_GI_COUNTERS 4 #define HTT_TX_PDEV_STATS_NUM_DCM_COUNTERS 5 #define HTT_TX_PDEV_STATS_NUM_BW_COUNTERS 4 #define HTT_TX_PDEV_STATS_NUM_SPATIAL_STREAMS 8 #define HTT_TX_PDEV_STATS_NUM_PREAMBLE_TYPES HTT_STATS_PREAM_COUNT #define HTT_TX_PDEV_STATS_NUM_LEGACY_CCK_STATS 4 #define HTT_TX_PDEV_STATS_NUM_LEGACY_OFDM_STATS 8 #define HTT_TX_PDEV_STATS_NUM_LTF 4 #define HTT_TX_NUM_OF_SOUNDING_STATS_WORDS \ (HTT_TX_PDEV_STATS_NUM_BW_COUNTERS * \ HTT_TX_PDEV_STATS_NUM_AX_MUMIMO_USER_STATS) struct htt_tx_pdev_rate_stats_tlv { u32 mac_id__word; u32 tx_ldpc; u32 rts_cnt; /* RSSI value of last ack packet (units = dB above noise floor) */ u32 ack_rssi; u32 tx_mcs[HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 tx_su_mcs[HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 tx_mu_mcs[HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; /* element 0,1, ...7 -> NSS 1,2, ...8 */ u32 tx_nss[HTT_TX_PDEV_STATS_NUM_SPATIAL_STREAMS]; /* element 0: 20 MHz, 1: 40 MHz, 2: 80 MHz, 3: 160 and 80+80 MHz */ u32 tx_bw[HTT_TX_PDEV_STATS_NUM_BW_COUNTERS]; u32 tx_stbc[HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 tx_pream[HTT_TX_PDEV_STATS_NUM_PREAMBLE_TYPES]; /* Counters to track number of tx packets * in each GI (400us, 800us, 1600us & 3200us) in each mcs (0-11) */ u32 tx_gi[HTT_TX_PDEV_STATS_NUM_GI_COUNTERS][HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; /* Counters to track packets in dcm mcs (MCS 0, 1, 3, 4) */ u32 tx_dcm[HTT_TX_PDEV_STATS_NUM_DCM_COUNTERS]; /* Number of CTS-acknowledged RTS packets */ u32 rts_success; /* * Counters for legacy 11a and 11b transmissions. * * The index corresponds to: * * CCK: 0: 1 Mbps, 1: 2 Mbps, 2: 5.5 Mbps, 3: 11 Mbps * * OFDM: 0: 6 Mbps, 1: 9 Mbps, 2: 12 Mbps, 3: 18 Mbps, * 4: 24 Mbps, 5: 36 Mbps, 6: 48 Mbps, 7: 54 Mbps */ u32 tx_legacy_cck_rate[HTT_TX_PDEV_STATS_NUM_LEGACY_CCK_STATS]; u32 tx_legacy_ofdm_rate[HTT_TX_PDEV_STATS_NUM_LEGACY_OFDM_STATS]; u32 ac_mu_mimo_tx_ldpc; u32 ax_mu_mimo_tx_ldpc; u32 ofdma_tx_ldpc; /* * Counters for 11ax HE LTF selection during TX. * * The index corresponds to: * * 0: unused, 1: 1x LTF, 2: 2x LTF, 3: 4x LTF */ u32 tx_he_ltf[HTT_TX_PDEV_STATS_NUM_LTF]; u32 ac_mu_mimo_tx_mcs[HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 ax_mu_mimo_tx_mcs[HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 ofdma_tx_mcs[HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 ac_mu_mimo_tx_nss[HTT_TX_PDEV_STATS_NUM_SPATIAL_STREAMS]; u32 ax_mu_mimo_tx_nss[HTT_TX_PDEV_STATS_NUM_SPATIAL_STREAMS]; u32 ofdma_tx_nss[HTT_TX_PDEV_STATS_NUM_SPATIAL_STREAMS]; u32 ac_mu_mimo_tx_bw[HTT_TX_PDEV_STATS_NUM_BW_COUNTERS]; u32 ax_mu_mimo_tx_bw[HTT_TX_PDEV_STATS_NUM_BW_COUNTERS]; u32 ofdma_tx_bw[HTT_TX_PDEV_STATS_NUM_BW_COUNTERS]; u32 ac_mu_mimo_tx_gi[HTT_TX_PDEV_STATS_NUM_GI_COUNTERS] [HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 ax_mu_mimo_tx_gi[HTT_TX_PDEV_STATS_NUM_GI_COUNTERS] [HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 ofdma_tx_gi[HTT_TX_PDEV_STATS_NUM_GI_COUNTERS] [HTT_TX_PDEV_STATS_NUM_MCS_COUNTERS]; }; /* == PDEV RX RATE CTRL STATS == */ #define HTT_RX_PDEV_STATS_NUM_LEGACY_CCK_STATS 4 #define HTT_RX_PDEV_STATS_NUM_LEGACY_OFDM_STATS 8 #define HTT_RX_PDEV_STATS_NUM_MCS_COUNTERS 12 #define HTT_RX_PDEV_STATS_NUM_GI_COUNTERS 4 #define HTT_RX_PDEV_STATS_NUM_DCM_COUNTERS 5 #define HTT_RX_PDEV_STATS_NUM_BW_COUNTERS 4 #define HTT_RX_PDEV_STATS_NUM_SPATIAL_STREAMS 8 #define HTT_RX_PDEV_STATS_NUM_PREAMBLE_TYPES HTT_STATS_PREAM_COUNT #define HTT_RX_PDEV_MAX_OFDMA_NUM_USER 8 #define HTT_RX_PDEV_STATS_RXEVM_MAX_PILOTS_PER_NSS 16 struct htt_rx_pdev_rate_stats_tlv { u32 mac_id__word; u32 nsts; u32 rx_ldpc; u32 rts_cnt; u32 rssi_mgmt; /* units = dB above noise floor */ u32 rssi_data; /* units = dB above noise floor */ u32 rssi_comb; /* units = dB above noise floor */ u32 rx_mcs[HTT_RX_PDEV_STATS_NUM_MCS_COUNTERS]; /* element 0,1, ...7 -> NSS 1,2, ...8 */ u32 rx_nss[HTT_RX_PDEV_STATS_NUM_SPATIAL_STREAMS]; u32 rx_dcm[HTT_RX_PDEV_STATS_NUM_DCM_COUNTERS]; u32 rx_stbc[HTT_RX_PDEV_STATS_NUM_MCS_COUNTERS]; /* element 0: 20 MHz, 1: 40 MHz, 2: 80 MHz, 3: 160 and 80+80 MHz */ u32 rx_bw[HTT_RX_PDEV_STATS_NUM_BW_COUNTERS]; u32 rx_pream[HTT_RX_PDEV_STATS_NUM_PREAMBLE_TYPES]; u8 rssi_chain[HTT_RX_PDEV_STATS_NUM_SPATIAL_STREAMS] [HTT_RX_PDEV_STATS_NUM_BW_COUNTERS]; /* units = dB above noise floor */ /* Counters to track number of rx packets * in each GI in each mcs (0-11) */ u32 rx_gi[HTT_RX_PDEV_STATS_NUM_GI_COUNTERS][HTT_RX_PDEV_STATS_NUM_MCS_COUNTERS]; s32 rssi_in_dbm; /* rx Signal Strength value in dBm unit */ u32 rx_11ax_su_ext; u32 rx_11ac_mumimo; u32 rx_11ax_mumimo; u32 rx_11ax_ofdma; u32 txbf; u32 rx_legacy_cck_rate[HTT_RX_PDEV_STATS_NUM_LEGACY_CCK_STATS]; u32 rx_legacy_ofdm_rate[HTT_RX_PDEV_STATS_NUM_LEGACY_OFDM_STATS]; u32 rx_active_dur_us_low; u32 rx_active_dur_us_high; u32 rx_11ax_ul_ofdma; u32 ul_ofdma_rx_mcs[HTT_RX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 ul_ofdma_rx_gi[HTT_TX_PDEV_STATS_NUM_GI_COUNTERS] [HTT_RX_PDEV_STATS_NUM_MCS_COUNTERS]; u32 ul_ofdma_rx_nss[HTT_TX_PDEV_STATS_NUM_SPATIAL_STREAMS]; u32 ul_ofdma_rx_bw[HTT_TX_PDEV_STATS_NUM_BW_COUNTERS]; u32 ul_ofdma_rx_stbc; u32 ul_ofdma_rx_ldpc; /* record the stats for each user index */ u32 rx_ulofdma_non_data_ppdu[HTT_RX_PDEV_MAX_OFDMA_NUM_USER]; /* ppdu level */ u32 rx_ulofdma_data_ppdu[HTT_RX_PDEV_MAX_OFDMA_NUM_USER]; /* ppdu level */ u32 rx_ulofdma_mpdu_ok[HTT_RX_PDEV_MAX_OFDMA_NUM_USER]; /* mpdu level */ u32 rx_ulofdma_mpdu_fail[HTT_RX_PDEV_MAX_OFDMA_NUM_USER]; /* mpdu level */ u32 nss_count; u32 pilot_count; /* RxEVM stats in dB */ s32 rx_pilot_evm_db[HTT_RX_PDEV_STATS_NUM_SPATIAL_STREAMS] [HTT_RX_PDEV_STATS_RXEVM_MAX_PILOTS_PER_NSS]; /* rx_pilot_evm_db_mean: * EVM mean across pilots, computed as * mean(10*log10(rx_pilot_evm_linear)) = mean(rx_pilot_evm_db) */ s32 rx_pilot_evm_db_mean[HTT_RX_PDEV_STATS_NUM_SPATIAL_STREAMS]; s8 rx_ul_fd_rssi[HTT_RX_PDEV_STATS_NUM_SPATIAL_STREAMS] [HTT_RX_PDEV_MAX_OFDMA_NUM_USER]; /* dBm units */ /* per_chain_rssi_pkt_type: * This field shows what type of rx frame the per-chain RSSI was computed * on, by recording the frame type and sub-type as bit-fields within this * field: * BIT [3 : 0] :- IEEE80211_FC0_TYPE * BIT [7 : 4] :- IEEE80211_FC0_SUBTYPE * BIT [31 : 8] :- Reserved */ u32 per_chain_rssi_pkt_type; s8 rx_per_chain_rssi_in_dbm[HTT_RX_PDEV_STATS_NUM_SPATIAL_STREAMS] [HTT_RX_PDEV_STATS_NUM_BW_COUNTERS]; }; /* == RX PDEV/SOC STATS == */ struct htt_rx_soc_fw_stats_tlv { u32 fw_reo_ring_data_msdu; u32 fw_to_host_data_msdu_bcmc; u32 fw_to_host_data_msdu_uc; u32 ofld_remote_data_buf_recycle_cnt; u32 ofld_remote_free_buf_indication_cnt; u32 ofld_buf_to_host_data_msdu_uc; u32 reo_fw_ring_to_host_data_msdu_uc; u32 wbm_sw_ring_reap; u32 wbm_forward_to_host_cnt; u32 wbm_target_recycle_cnt; u32 target_refill_ring_recycle_cnt; }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_rx_soc_fw_refill_ring_empty_tlv_v { u32 refill_ring_empty_cnt[0]; /* HTT_RX_STATS_REFILL_MAX_RING */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_rx_soc_fw_refill_ring_num_refill_tlv_v { u32 refill_ring_num_refill[0]; /* HTT_RX_STATS_REFILL_MAX_RING */ }; /* RXDMA error code from WBM released packets */ enum htt_rx_rxdma_error_code_enum { HTT_RX_RXDMA_OVERFLOW_ERR = 0, HTT_RX_RXDMA_MPDU_LENGTH_ERR = 1, HTT_RX_RXDMA_FCS_ERR = 2, HTT_RX_RXDMA_DECRYPT_ERR = 3, HTT_RX_RXDMA_TKIP_MIC_ERR = 4, HTT_RX_RXDMA_UNECRYPTED_ERR = 5, HTT_RX_RXDMA_MSDU_LEN_ERR = 6, HTT_RX_RXDMA_MSDU_LIMIT_ERR = 7, HTT_RX_RXDMA_WIFI_PARSE_ERR = 8, HTT_RX_RXDMA_AMSDU_PARSE_ERR = 9, HTT_RX_RXDMA_SA_TIMEOUT_ERR = 10, HTT_RX_RXDMA_DA_TIMEOUT_ERR = 11, HTT_RX_RXDMA_FLOW_TIMEOUT_ERR = 12, HTT_RX_RXDMA_FLUSH_REQUEST = 13, HTT_RX_RXDMA_ERR_CODE_RVSD0 = 14, HTT_RX_RXDMA_ERR_CODE_RVSD1 = 15, /* This MAX_ERR_CODE should not be used in any host/target messages, * so that even though it is defined within a host/target interface * definition header file, it isn't actually part of the host/target * interface, and thus can be modified. */ HTT_RX_RXDMA_MAX_ERR_CODE }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_rx_soc_fw_refill_ring_num_rxdma_err_tlv_v { u32 rxdma_err[0]; /* HTT_RX_RXDMA_MAX_ERR_CODE */ }; /* REO error code from WBM released packets */ enum htt_rx_reo_error_code_enum { HTT_RX_REO_QUEUE_DESC_ADDR_ZERO = 0, HTT_RX_REO_QUEUE_DESC_NOT_VALID = 1, HTT_RX_AMPDU_IN_NON_BA = 2, HTT_RX_NON_BA_DUPLICATE = 3, HTT_RX_BA_DUPLICATE = 4, HTT_RX_REGULAR_FRAME_2K_JUMP = 5, HTT_RX_BAR_FRAME_2K_JUMP = 6, HTT_RX_REGULAR_FRAME_OOR = 7, HTT_RX_BAR_FRAME_OOR = 8, HTT_RX_BAR_FRAME_NO_BA_SESSION = 9, HTT_RX_BAR_FRAME_SN_EQUALS_SSN = 10, HTT_RX_PN_CHECK_FAILED = 11, HTT_RX_2K_ERROR_HANDLING_FLAG_SET = 12, HTT_RX_PN_ERROR_HANDLING_FLAG_SET = 13, HTT_RX_QUEUE_DESCRIPTOR_BLOCKED_SET = 14, HTT_RX_REO_ERR_CODE_RVSD = 15, /* This MAX_ERR_CODE should not be used in any host/target messages, * so that even though it is defined within a host/target interface * definition header file, it isn't actually part of the host/target * interface, and thus can be modified. */ HTT_RX_REO_MAX_ERR_CODE }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_rx_soc_fw_refill_ring_num_reo_err_tlv_v { u32 reo_err[0]; /* HTT_RX_REO_MAX_ERR_CODE */ }; /* == RX PDEV STATS == */ #define HTT_STATS_SUBTYPE_MAX 16 struct htt_rx_pdev_fw_stats_tlv { u32 mac_id__word; u32 ppdu_recvd; u32 mpdu_cnt_fcs_ok; u32 mpdu_cnt_fcs_err; u32 tcp_msdu_cnt; u32 tcp_ack_msdu_cnt; u32 udp_msdu_cnt; u32 other_msdu_cnt; u32 fw_ring_mpdu_ind; u32 fw_ring_mgmt_subtype[HTT_STATS_SUBTYPE_MAX]; u32 fw_ring_ctrl_subtype[HTT_STATS_SUBTYPE_MAX]; u32 fw_ring_mcast_data_msdu; u32 fw_ring_bcast_data_msdu; u32 fw_ring_ucast_data_msdu; u32 fw_ring_null_data_msdu; u32 fw_ring_mpdu_drop; u32 ofld_local_data_ind_cnt; u32 ofld_local_data_buf_recycle_cnt; u32 drx_local_data_ind_cnt; u32 drx_local_data_buf_recycle_cnt; u32 local_nondata_ind_cnt; u32 local_nondata_buf_recycle_cnt; u32 fw_status_buf_ring_refill_cnt; u32 fw_status_buf_ring_empty_cnt; u32 fw_pkt_buf_ring_refill_cnt; u32 fw_pkt_buf_ring_empty_cnt; u32 fw_link_buf_ring_refill_cnt; u32 fw_link_buf_ring_empty_cnt; u32 host_pkt_buf_ring_refill_cnt; u32 host_pkt_buf_ring_empty_cnt; u32 mon_pkt_buf_ring_refill_cnt; u32 mon_pkt_buf_ring_empty_cnt; u32 mon_status_buf_ring_refill_cnt; u32 mon_status_buf_ring_empty_cnt; u32 mon_desc_buf_ring_refill_cnt; u32 mon_desc_buf_ring_empty_cnt; u32 mon_dest_ring_update_cnt; u32 mon_dest_ring_full_cnt; u32 rx_suspend_cnt; u32 rx_suspend_fail_cnt; u32 rx_resume_cnt; u32 rx_resume_fail_cnt; u32 rx_ring_switch_cnt; u32 rx_ring_restore_cnt; u32 rx_flush_cnt; u32 rx_recovery_reset_cnt; }; #define HTT_STATS_PHY_ERR_MAX 43 struct htt_rx_pdev_fw_stats_phy_err_tlv { u32 mac_id__word; u32 total_phy_err_cnt; /* Counts of different types of phy errs * The mapping of PHY error types to phy_err array elements is HW dependent. * The only currently-supported mapping is shown below: * * 0 phyrx_err_phy_off Reception aborted due to receiving a PHY_OFF TLV * 1 phyrx_err_synth_off * 2 phyrx_err_ofdma_timing * 3 phyrx_err_ofdma_signal_parity * 4 phyrx_err_ofdma_rate_illegal * 5 phyrx_err_ofdma_length_illegal * 6 phyrx_err_ofdma_restart * 7 phyrx_err_ofdma_service * 8 phyrx_err_ppdu_ofdma_power_drop * 9 phyrx_err_cck_blokker * 10 phyrx_err_cck_timing * 11 phyrx_err_cck_header_crc * 12 phyrx_err_cck_rate_illegal * 13 phyrx_err_cck_length_illegal * 14 phyrx_err_cck_restart * 15 phyrx_err_cck_service * 16 phyrx_err_cck_power_drop * 17 phyrx_err_ht_crc_err * 18 phyrx_err_ht_length_illegal * 19 phyrx_err_ht_rate_illegal * 20 phyrx_err_ht_zlf * 21 phyrx_err_false_radar_ext * 22 phyrx_err_green_field * 23 phyrx_err_bw_gt_dyn_bw * 24 phyrx_err_leg_ht_mismatch * 25 phyrx_err_vht_crc_error * 26 phyrx_err_vht_siga_unsupported * 27 phyrx_err_vht_lsig_len_invalid * 28 phyrx_err_vht_ndp_or_zlf * 29 phyrx_err_vht_nsym_lt_zero * 30 phyrx_err_vht_rx_extra_symbol_mismatch * 31 phyrx_err_vht_rx_skip_group_id0 * 32 phyrx_err_vht_rx_skip_group_id1to62 * 33 phyrx_err_vht_rx_skip_group_id63 * 34 phyrx_err_ofdm_ldpc_decoder_disabled * 35 phyrx_err_defer_nap * 36 phyrx_err_fdomain_timeout * 37 phyrx_err_lsig_rel_check * 38 phyrx_err_bt_collision * 39 phyrx_err_unsupported_mu_feedback * 40 phyrx_err_ppdu_tx_interrupt_rx * 41 phyrx_err_unsupported_cbf * 42 phyrx_err_other */ u32 phy_err[HTT_STATS_PHY_ERR_MAX]; }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_rx_pdev_fw_ring_mpdu_err_tlv_v { /* Num error MPDU for each RxDMA error type */ u32 fw_ring_mpdu_err[0]; /* HTT_RX_STATS_RXDMA_MAX_ERR */ }; /* NOTE: Variable length TLV, use length spec to infer array size */ struct htt_rx_pdev_fw_mpdu_drop_tlv_v { /* Num MPDU dropped */ u32 fw_mpdu_drop[0]; /* HTT_RX_STATS_FW_DROP_REASON_MAX */ }; #define HTT_PDEV_CCA_STATS_TX_FRAME_INFO_PRESENT (0x1) #define HTT_PDEV_CCA_STATS_RX_FRAME_INFO_PRESENT (0x2) #define HTT_PDEV_CCA_STATS_RX_CLEAR_INFO_PRESENT (0x4) #define HTT_PDEV_CCA_STATS_MY_RX_FRAME_INFO_PRESENT (0x8) #define HTT_PDEV_CCA_STATS_USEC_CNT_INFO_PRESENT (0x10) #define HTT_PDEV_CCA_STATS_MED_RX_IDLE_INFO_PRESENT (0x20) #define HTT_PDEV_CCA_STATS_MED_TX_IDLE_GLOBAL_INFO_PRESENT (0x40) #define HTT_PDEV_CCA_STATS_CCA_OBBS_USEC_INFO_PRESENT (0x80) struct htt_pdev_stats_cca_counters_tlv { /* Below values are obtained from the HW Cycles counter registers */ u32 tx_frame_usec; u32 rx_frame_usec; u32 rx_clear_usec; u32 my_rx_frame_usec; u32 usec_cnt; u32 med_rx_idle_usec; u32 med_tx_idle_global_usec; u32 cca_obss_usec; }; struct htt_pdev_cca_stats_hist_v1_tlv { u32 chan_num; /* num of CCA records (Num of htt_pdev_stats_cca_counters_tlv)*/ u32 num_records; u32 valid_cca_counters_bitmap; u32 collection_interval; /* This will be followed by an array which contains the CCA stats * collected in the last N intervals, * if the indication is for last N intervals CCA stats. * Then the pdev_cca_stats[0] element contains the oldest CCA stats * and pdev_cca_stats[N-1] will have the most recent CCA stats. * htt_pdev_stats_cca_counters_tlv cca_hist_tlv[1]; */ }; struct htt_pdev_stats_twt_session_tlv { u32 vdev_id; struct htt_mac_addr peer_mac; u32 flow_id_flags; /* TWT_DIALOG_ID_UNAVAILABLE is used * when TWT session is not initiated by host */ u32 dialog_id; u32 wake_dura_us; u32 wake_intvl_us; u32 sp_offset_us; }; struct htt_pdev_stats_twt_sessions_tlv { u32 pdev_id; u32 num_sessions; struct htt_pdev_stats_twt_session_tlv twt_session[]; }; enum htt_rx_reo_resource_sample_id_enum { /* Global link descriptor queued in REO */ HTT_RX_REO_RESOURCE_GLOBAL_LINK_DESC_COUNT_0 = 0, HTT_RX_REO_RESOURCE_GLOBAL_LINK_DESC_COUNT_1 = 1, HTT_RX_REO_RESOURCE_GLOBAL_LINK_DESC_COUNT_2 = 2, /*Number of queue descriptors of this aging group */ HTT_RX_REO_RESOURCE_BUFFERS_USED_AC0 = 3, HTT_RX_REO_RESOURCE_BUFFERS_USED_AC1 = 4, HTT_RX_REO_RESOURCE_BUFFERS_USED_AC2 = 5, HTT_RX_REO_RESOURCE_BUFFERS_USED_AC3 = 6, /* Total number of MSDUs buffered in AC */ HTT_RX_REO_RESOURCE_AGING_NUM_QUEUES_AC0 = 7, HTT_RX_REO_RESOURCE_AGING_NUM_QUEUES_AC1 = 8, HTT_RX_REO_RESOURCE_AGING_NUM_QUEUES_AC2 = 9, HTT_RX_REO_RESOURCE_AGING_NUM_QUEUES_AC3 = 10, HTT_RX_REO_RESOURCE_STATS_MAX = 16 }; struct htt_rx_reo_resource_stats_tlv_v { /* Variable based on the Number of records. HTT_RX_REO_RESOURCE_STATS_MAX */ u32 sample_id; u32 total_max; u32 total_avg; u32 total_sample; u32 non_zeros_avg; u32 non_zeros_sample; u32 last_non_zeros_max; u32 last_non_zeros_min; u32 last_non_zeros_avg; u32 last_non_zeros_sample; }; /* == TX SOUNDING STATS == */ enum htt_txbf_sound_steer_modes { HTT_IMPLICIT_TXBF_STEER_STATS = 0, HTT_EXPLICIT_TXBF_SU_SIFS_STEER_STATS = 1, HTT_EXPLICIT_TXBF_SU_RBO_STEER_STATS = 2, HTT_EXPLICIT_TXBF_MU_SIFS_STEER_STATS = 3, HTT_EXPLICIT_TXBF_MU_RBO_STEER_STATS = 4, HTT_TXBF_MAX_NUM_OF_MODES = 5 }; enum htt_stats_sounding_tx_mode { HTT_TX_AC_SOUNDING_MODE = 0, HTT_TX_AX_SOUNDING_MODE = 1, }; struct htt_tx_sounding_stats_tlv { u32 tx_sounding_mode; /* HTT_TX_XX_SOUNDING_MODE */ /* Counts number of soundings for all steering modes in each bw */ u32 cbf_20[HTT_TXBF_MAX_NUM_OF_MODES]; u32 cbf_40[HTT_TXBF_MAX_NUM_OF_MODES]; u32 cbf_80[HTT_TXBF_MAX_NUM_OF_MODES]; u32 cbf_160[HTT_TXBF_MAX_NUM_OF_MODES]; /* * The sounding array is a 2-D array stored as an 1-D array of * u32. The stats for a particular user/bw combination is * referenced with the following: * * sounding[(user* max_bw) + bw] * * ... where max_bw == 4 for 160mhz */ u32 sounding[HTT_TX_NUM_OF_SOUNDING_STATS_WORDS]; }; struct htt_pdev_obss_pd_stats_tlv { u32 num_obss_tx_ppdu_success; u32 num_obss_tx_ppdu_failure; }; struct htt_ring_backpressure_stats_tlv { u32 pdev_id; u32 current_head_idx; u32 current_tail_idx; u32 num_htt_msgs_sent; /* Time in milliseconds for which the ring has been in * its current backpressure condition */ u32 backpressure_time_ms; /* backpressure_hist - histogram showing how many times * different degrees of backpressure duration occurred: * Index 0 indicates the number of times ring was * continuously in backpressure state for 100 - 200ms. * Index 1 indicates the number of times ring was * continuously in backpressure state for 200 - 300ms. * Index 2 indicates the number of times ring was * continuously in backpressure state for 300 - 400ms. * Index 3 indicates the number of times ring was * continuously in backpressure state for 400 - 500ms. * Index 4 indicates the number of times ring was * continuously in backpressure state beyond 500ms. */ u32 backpressure_hist[5]; }; #ifdef CONFIG_ATH11K_DEBUGFS void ath11k_debugfs_htt_stats_init(struct ath11k *ar); void ath11k_debugfs_htt_ext_stats_handler(struct ath11k_base *ab, struct sk_buff *skb); int ath11k_debugfs_htt_stats_req(struct ath11k *ar); #else /* CONFIG_ATH11K_DEBUGFS */ static inline void ath11k_debugfs_htt_stats_init(struct ath11k *ar) { } static inline void ath11k_debugfs_htt_ext_stats_handler(struct ath11k_base *ab, struct sk_buff *skb) { } static inline int ath11k_debugfs_htt_stats_req(struct ath11k *ar) { return 0; } #endif /* CONFIG_ATH11K_DEBUGFS */ #endif