Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Zong-Zhe Yang | 8799 | 90.37% | 25 | 69.44% |
Ping-Ke Shih | 770 | 7.91% | 8 | 22.22% |
Po-Hao Huang | 145 | 1.49% | 2 | 5.56% |
Chin-Yen Lee | 23 | 0.24% | 1 | 2.78% |
Total | 9737 | 36 |
// SPDX-License-Identifier: GPL-2.0 OR BSD-3-Clause /* Copyright(c) 2020-2022 Realtek Corporation */ #include "chan.h" #include "coex.h" #include "debug.h" #include "fw.h" #include "mac.h" #include "ps.h" #include "util.h" static enum rtw89_subband rtw89_get_subband_type(enum rtw89_band band, u8 center_chan) { switch (band) { default: case RTW89_BAND_2G: switch (center_chan) { default: case 1 ... 14: return RTW89_CH_2G; } case RTW89_BAND_5G: switch (center_chan) { default: case 36 ... 64: return RTW89_CH_5G_BAND_1; case 100 ... 144: return RTW89_CH_5G_BAND_3; case 149 ... 177: return RTW89_CH_5G_BAND_4; } case RTW89_BAND_6G: switch (center_chan) { default: case 1 ... 29: return RTW89_CH_6G_BAND_IDX0; case 33 ... 61: return RTW89_CH_6G_BAND_IDX1; case 65 ... 93: return RTW89_CH_6G_BAND_IDX2; case 97 ... 125: return RTW89_CH_6G_BAND_IDX3; case 129 ... 157: return RTW89_CH_6G_BAND_IDX4; case 161 ... 189: return RTW89_CH_6G_BAND_IDX5; case 193 ... 221: return RTW89_CH_6G_BAND_IDX6; case 225 ... 253: return RTW89_CH_6G_BAND_IDX7; } } } static enum rtw89_sc_offset rtw89_get_primary_chan_idx(enum rtw89_bandwidth bw, u32 center_freq, u32 primary_freq) { u8 primary_chan_idx; u32 offset; switch (bw) { default: case RTW89_CHANNEL_WIDTH_20: primary_chan_idx = RTW89_SC_DONT_CARE; break; case RTW89_CHANNEL_WIDTH_40: if (primary_freq > center_freq) primary_chan_idx = RTW89_SC_20_UPPER; else primary_chan_idx = RTW89_SC_20_LOWER; break; case RTW89_CHANNEL_WIDTH_80: case RTW89_CHANNEL_WIDTH_160: if (primary_freq > center_freq) { offset = (primary_freq - center_freq - 10) / 20; primary_chan_idx = RTW89_SC_20_UPPER + offset * 2; } else { offset = (center_freq - primary_freq - 10) / 20; primary_chan_idx = RTW89_SC_20_LOWER + offset * 2; } break; } return primary_chan_idx; } static u8 rtw89_get_primary_sb_idx(u8 central_ch, u8 pri_ch, enum rtw89_bandwidth bw) { static const u8 prisb_cal_ofst[RTW89_CHANNEL_WIDTH_ORDINARY_NUM] = { 0, 2, 6, 14, 30 }; if (bw >= RTW89_CHANNEL_WIDTH_ORDINARY_NUM) return 0; return (prisb_cal_ofst[bw] + pri_ch - central_ch) / 4; } void rtw89_chan_create(struct rtw89_chan *chan, u8 center_chan, u8 primary_chan, enum rtw89_band band, enum rtw89_bandwidth bandwidth) { enum nl80211_band nl_band = rtw89_hw_to_nl80211_band(band); u32 center_freq, primary_freq; memset(chan, 0, sizeof(*chan)); chan->channel = center_chan; chan->primary_channel = primary_chan; chan->band_type = band; chan->band_width = bandwidth; center_freq = ieee80211_channel_to_frequency(center_chan, nl_band); primary_freq = ieee80211_channel_to_frequency(primary_chan, nl_band); chan->freq = center_freq; chan->subband_type = rtw89_get_subband_type(band, center_chan); chan->pri_ch_idx = rtw89_get_primary_chan_idx(bandwidth, center_freq, primary_freq); chan->pri_sb_idx = rtw89_get_primary_sb_idx(center_chan, primary_chan, bandwidth); } bool rtw89_assign_entity_chan(struct rtw89_dev *rtwdev, enum rtw89_sub_entity_idx idx, const struct rtw89_chan *new) { struct rtw89_hal *hal = &rtwdev->hal; struct rtw89_chan *chan = &hal->sub[idx].chan; struct rtw89_chan_rcd *rcd = &hal->sub[idx].rcd; bool band_changed; rcd->prev_primary_channel = chan->primary_channel; rcd->prev_band_type = chan->band_type; band_changed = new->band_type != chan->band_type; rcd->band_changed = band_changed; *chan = *new; return band_changed; } static void __rtw89_config_entity_chandef(struct rtw89_dev *rtwdev, enum rtw89_sub_entity_idx idx, const struct cfg80211_chan_def *chandef, bool from_stack) { struct rtw89_hal *hal = &rtwdev->hal; hal->sub[idx].chandef = *chandef; if (from_stack) set_bit(idx, hal->entity_map); } void rtw89_config_entity_chandef(struct rtw89_dev *rtwdev, enum rtw89_sub_entity_idx idx, const struct cfg80211_chan_def *chandef) { __rtw89_config_entity_chandef(rtwdev, idx, chandef, true); } void rtw89_config_roc_chandef(struct rtw89_dev *rtwdev, enum rtw89_sub_entity_idx idx, const struct cfg80211_chan_def *chandef) { struct rtw89_hal *hal = &rtwdev->hal; enum rtw89_sub_entity_idx cur; if (chandef) { cur = atomic_cmpxchg(&hal->roc_entity_idx, RTW89_SUB_ENTITY_IDLE, idx); if (cur != RTW89_SUB_ENTITY_IDLE) { rtw89_debug(rtwdev, RTW89_DBG_TXRX, "ROC still processing on entity %d\n", idx); return; } hal->roc_chandef = *chandef; } else { cur = atomic_cmpxchg(&hal->roc_entity_idx, idx, RTW89_SUB_ENTITY_IDLE); if (cur == idx) return; if (cur == RTW89_SUB_ENTITY_IDLE) rtw89_debug(rtwdev, RTW89_DBG_TXRX, "ROC already finished on entity %d\n", idx); else rtw89_debug(rtwdev, RTW89_DBG_TXRX, "ROC is processing on entity %d\n", cur); } } static void rtw89_config_default_chandef(struct rtw89_dev *rtwdev) { struct cfg80211_chan_def chandef = {0}; rtw89_get_default_chandef(&chandef); __rtw89_config_entity_chandef(rtwdev, RTW89_SUB_ENTITY_0, &chandef, false); } void rtw89_entity_init(struct rtw89_dev *rtwdev) { struct rtw89_hal *hal = &rtwdev->hal; hal->entity_pause = false; bitmap_zero(hal->entity_map, NUM_OF_RTW89_SUB_ENTITY); bitmap_zero(hal->changes, NUM_OF_RTW89_CHANCTX_CHANGES); atomic_set(&hal->roc_entity_idx, RTW89_SUB_ENTITY_IDLE); rtw89_config_default_chandef(rtwdev); } enum rtw89_entity_mode rtw89_entity_recalc(struct rtw89_dev *rtwdev) { struct rtw89_hal *hal = &rtwdev->hal; const struct cfg80211_chan_def *chandef; enum rtw89_entity_mode mode; struct rtw89_chan chan; u8 weight; u8 last; u8 idx; lockdep_assert_held(&rtwdev->mutex); weight = bitmap_weight(hal->entity_map, NUM_OF_RTW89_SUB_ENTITY); switch (weight) { default: rtw89_warn(rtwdev, "unknown ent chan weight: %d\n", weight); bitmap_zero(hal->entity_map, NUM_OF_RTW89_SUB_ENTITY); fallthrough; case 0: rtw89_config_default_chandef(rtwdev); fallthrough; case 1: last = RTW89_SUB_ENTITY_0; mode = RTW89_ENTITY_MODE_SCC; break; case 2: last = RTW89_SUB_ENTITY_1; mode = rtw89_get_entity_mode(rtwdev); if (mode == RTW89_ENTITY_MODE_MCC) break; mode = RTW89_ENTITY_MODE_MCC_PREPARE; break; } for (idx = 0; idx <= last; idx++) { chandef = rtw89_chandef_get(rtwdev, idx); rtw89_get_channel_params(chandef, &chan); if (chan.channel == 0) { WARN(1, "Invalid channel on chanctx %d\n", idx); return RTW89_ENTITY_MODE_INVALID; } rtw89_assign_entity_chan(rtwdev, idx, &chan); } if (hal->entity_pause) return rtw89_get_entity_mode(rtwdev); rtw89_set_entity_mode(rtwdev, mode); return mode; } static void rtw89_chanctx_notify(struct rtw89_dev *rtwdev, enum rtw89_chanctx_state state) { const struct rtw89_chip_info *chip = rtwdev->chip; const struct rtw89_chanctx_listener *listener = chip->chanctx_listener; int i; if (!listener) return; for (i = 0; i < NUM_OF_RTW89_CHANCTX_CALLBACKS; i++) { if (!listener->callbacks[i]) continue; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "chanctx notify listener: cb %d, state %d\n", i, state); listener->callbacks[i](rtwdev, state); } } /* This function centrally manages how MCC roles are sorted and iterated. * And, it guarantees that ordered_idx is less than NUM_OF_RTW89_MCC_ROLES. * So, if data needs to pass an array for ordered_idx, the array can declare * with NUM_OF_RTW89_MCC_ROLES. Besides, the entire iteration will stop * immediately as long as iterator returns a non-zero value. */ static int rtw89_iterate_mcc_roles(struct rtw89_dev *rtwdev, int (*iterator)(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role, unsigned int ordered_idx, void *data), void *data) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role * const roles[] = { &mcc->role_ref, &mcc->role_aux, }; unsigned int idx; int ret; BUILD_BUG_ON(ARRAY_SIZE(roles) != NUM_OF_RTW89_MCC_ROLES); for (idx = 0; idx < NUM_OF_RTW89_MCC_ROLES; idx++) { ret = iterator(rtwdev, roles[idx], idx, data); if (ret) return ret; } return 0; } /* For now, IEEE80211_HW_TIMING_BEACON_ONLY can make things simple to ensure * correctness of MCC calculation logic below. We have noticed that once driver * declares WIPHY_FLAG_SUPPORTS_MLO, the use of IEEE80211_HW_TIMING_BEACON_ONLY * will be restricted. We will make an alternative in driver when it is ready * for MLO. */ static u32 rtw89_mcc_get_tbtt_ofst(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *role, u64 tsf) { struct rtw89_vif *rtwvif = role->rtwvif; struct ieee80211_vif *vif = rtwvif_to_vif(rtwvif); u32 bcn_intvl_us = ieee80211_tu_to_usec(role->beacon_interval); u64 sync_tsf = vif->bss_conf.sync_tsf; u32 remainder; if (tsf < sync_tsf) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC get tbtt ofst: tsf might not update yet\n"); sync_tsf = 0; } div_u64_rem(tsf - sync_tsf, bcn_intvl_us, &remainder); return remainder; } static u16 rtw89_mcc_get_bcn_ofst(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mac_mcc_tsf_rpt rpt = {}; struct rtw89_fw_mcc_tsf_req req = {}; u32 bcn_intvl_ref_us = ieee80211_tu_to_usec(ref->beacon_interval); u32 tbtt_ofst_ref, tbtt_ofst_aux; u64 tsf_ref, tsf_aux; int ret; req.group = mcc->group; req.macid_x = ref->rtwvif->mac_id; req.macid_y = aux->rtwvif->mac_id; ret = rtw89_fw_h2c_mcc_req_tsf(rtwdev, &req, &rpt); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to request tsf: %d\n", ret); return RTW89_MCC_DFLT_BCN_OFST_TIME; } tsf_ref = (u64)rpt.tsf_x_high << 32 | rpt.tsf_x_low; tsf_aux = (u64)rpt.tsf_y_high << 32 | rpt.tsf_y_low; tbtt_ofst_ref = rtw89_mcc_get_tbtt_ofst(rtwdev, ref, tsf_ref); tbtt_ofst_aux = rtw89_mcc_get_tbtt_ofst(rtwdev, aux, tsf_aux); while (tbtt_ofst_ref < tbtt_ofst_aux) tbtt_ofst_ref += bcn_intvl_ref_us; return (tbtt_ofst_ref - tbtt_ofst_aux) / 1024; } static void rtw89_mcc_role_fw_macid_bitmap_set_bit(struct rtw89_mcc_role *mcc_role, unsigned int bit) { unsigned int idx = bit / 8; unsigned int pos = bit % 8; if (idx >= ARRAY_SIZE(mcc_role->macid_bitmap)) return; mcc_role->macid_bitmap[idx] |= BIT(pos); } static void rtw89_mcc_role_macid_sta_iter(void *data, struct ieee80211_sta *sta) { struct rtw89_sta *rtwsta = (struct rtw89_sta *)sta->drv_priv; struct rtw89_vif *rtwvif = rtwsta->rtwvif; struct rtw89_mcc_role *mcc_role = data; struct rtw89_vif *target = mcc_role->rtwvif; if (rtwvif != target) return; rtw89_mcc_role_fw_macid_bitmap_set_bit(mcc_role, rtwsta->mac_id); } static void rtw89_mcc_fill_role_macid_bitmap(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role) { struct rtw89_vif *rtwvif = mcc_role->rtwvif; rtw89_mcc_role_fw_macid_bitmap_set_bit(mcc_role, rtwvif->mac_id); ieee80211_iterate_stations_atomic(rtwdev->hw, rtw89_mcc_role_macid_sta_iter, mcc_role); } static void rtw89_mcc_fill_role_policy(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role) { struct rtw89_mcc_policy *policy = &mcc_role->policy; policy->c2h_rpt = RTW89_FW_MCC_C2H_RPT_ALL; policy->tx_null_early = RTW89_MCC_DFLT_TX_NULL_EARLY; policy->in_curr_ch = false; policy->dis_sw_retry = true; policy->sw_retry_count = false; if (mcc_role->is_go) policy->dis_tx_null = true; else policy->dis_tx_null = false; } static void rtw89_mcc_fill_role_limit(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role) { struct ieee80211_vif *vif = rtwvif_to_vif(mcc_role->rtwvif); struct ieee80211_p2p_noa_desc *noa_desc; u32 bcn_intvl_us = ieee80211_tu_to_usec(mcc_role->beacon_interval); u32 max_toa_us, max_tob_us, max_dur_us; u32 start_time, interval, duration; u64 tsf, tsf_lmt; int ret; int i; if (!mcc_role->is_go && !mcc_role->is_gc) return; /* find the first periodic NoA */ for (i = 0; i < RTW89_P2P_MAX_NOA_NUM; i++) { noa_desc = &vif->bss_conf.p2p_noa_attr.desc[i]; if (noa_desc->count == 255) goto fill; } return; fill: start_time = le32_to_cpu(noa_desc->start_time); interval = le32_to_cpu(noa_desc->interval); duration = le32_to_cpu(noa_desc->duration); if (interval != bcn_intvl_us) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC role limit: mismatch interval: %d vs. %d\n", interval, bcn_intvl_us); return; } ret = rtw89_mac_port_get_tsf(rtwdev, mcc_role->rtwvif, &tsf); if (ret) { rtw89_warn(rtwdev, "MCC failed to get port tsf: %d\n", ret); return; } tsf_lmt = (tsf & GENMASK_ULL(63, 32)) | start_time; max_toa_us = rtw89_mcc_get_tbtt_ofst(rtwdev, mcc_role, tsf_lmt); max_dur_us = interval - duration; max_tob_us = max_dur_us - max_toa_us; if (!max_toa_us || !max_tob_us) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC role limit: hit boundary\n"); return; } if (max_dur_us < max_toa_us) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC role limit: insufficient duration\n"); return; } mcc_role->limit.max_toa = max_toa_us / 1024; mcc_role->limit.max_tob = max_tob_us / 1024; mcc_role->limit.max_dur = max_dur_us / 1024; mcc_role->limit.enable = true; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC role limit: max_toa %d, max_tob %d, max_dur %d\n", mcc_role->limit.max_toa, mcc_role->limit.max_tob, mcc_role->limit.max_dur); } static int rtw89_mcc_fill_role(struct rtw89_dev *rtwdev, struct rtw89_vif *rtwvif, struct rtw89_mcc_role *role) { struct ieee80211_vif *vif = rtwvif_to_vif(rtwvif); const struct rtw89_chan *chan; memset(role, 0, sizeof(*role)); role->rtwvif = rtwvif; role->beacon_interval = vif->bss_conf.beacon_int; if (!role->beacon_interval) { rtw89_warn(rtwdev, "cannot handle MCC role without beacon interval\n"); return -EINVAL; } role->duration = role->beacon_interval / 2; chan = rtw89_chan_get(rtwdev, rtwvif->sub_entity_idx); role->is_2ghz = chan->band_type == RTW89_BAND_2G; role->is_go = rtwvif->wifi_role == RTW89_WIFI_ROLE_P2P_GO; role->is_gc = rtwvif->wifi_role == RTW89_WIFI_ROLE_P2P_CLIENT; rtw89_mcc_fill_role_macid_bitmap(rtwdev, role); rtw89_mcc_fill_role_policy(rtwdev, role); rtw89_mcc_fill_role_limit(rtwdev, role); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC role: bcn_intvl %d, is_2ghz %d, is_go %d, is_gc %d\n", role->beacon_interval, role->is_2ghz, role->is_go, role->is_gc); return 0; } static void rtw89_mcc_fill_bt_role(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_bt_role *bt_role = &mcc->bt_role; memset(bt_role, 0, sizeof(*bt_role)); bt_role->duration = rtw89_coex_query_bt_req_len(rtwdev, RTW89_PHY_0); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC bt role: dur %d\n", bt_role->duration); } struct rtw89_mcc_fill_role_selector { struct rtw89_vif *bind_vif[NUM_OF_RTW89_SUB_ENTITY]; }; static_assert((u8)NUM_OF_RTW89_SUB_ENTITY >= NUM_OF_RTW89_MCC_ROLES); static int rtw89_mcc_fill_role_iterator(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role, unsigned int ordered_idx, void *data) { struct rtw89_mcc_fill_role_selector *sel = data; struct rtw89_vif *role_vif = sel->bind_vif[ordered_idx]; int ret; if (!role_vif) { rtw89_warn(rtwdev, "cannot handle MCC without role[%d]\n", ordered_idx); return -EINVAL; } rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC fill role[%d] with vif <macid %d>\n", ordered_idx, role_vif->mac_id); ret = rtw89_mcc_fill_role(rtwdev, role_vif, mcc_role); if (ret) return ret; return 0; } static int rtw89_mcc_fill_all_roles(struct rtw89_dev *rtwdev) { struct rtw89_mcc_fill_role_selector sel = {}; struct rtw89_vif *rtwvif; int ret; rtw89_for_each_rtwvif(rtwdev, rtwvif) { if (sel.bind_vif[rtwvif->sub_entity_idx]) { rtw89_warn(rtwdev, "MCC skip extra vif <macid %d> on chanctx[%d]\n", rtwvif->mac_id, rtwvif->sub_entity_idx); continue; } sel.bind_vif[rtwvif->sub_entity_idx] = rtwvif; } ret = rtw89_iterate_mcc_roles(rtwdev, rtw89_mcc_fill_role_iterator, &sel); if (ret) return ret; rtw89_mcc_fill_bt_role(rtwdev); return 0; } static void rtw89_mcc_assign_pattern(struct rtw89_dev *rtwdev, const struct rtw89_mcc_pattern *new) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_pattern *pattern = &config->pattern; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC assign pattern: ref {%d | %d}, aux {%d | %d}\n", new->tob_ref, new->toa_ref, new->tob_aux, new->toa_aux); *pattern = *new; memset(&pattern->courtesy, 0, sizeof(pattern->courtesy)); if (pattern->tob_aux <= 0 || pattern->toa_aux <= 0) { pattern->courtesy.macid_tgt = aux->rtwvif->mac_id; pattern->courtesy.macid_src = ref->rtwvif->mac_id; pattern->courtesy.slot_num = RTW89_MCC_DFLT_COURTESY_SLOT; pattern->courtesy.enable = true; } else if (pattern->tob_ref <= 0 || pattern->toa_ref <= 0) { pattern->courtesy.macid_tgt = ref->rtwvif->mac_id; pattern->courtesy.macid_src = aux->rtwvif->mac_id; pattern->courtesy.slot_num = RTW89_MCC_DFLT_COURTESY_SLOT; pattern->courtesy.enable = true; } rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC pattern flags: plan %d, courtesy_en %d\n", pattern->plan, pattern->courtesy.enable); if (!pattern->courtesy.enable) return; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC pattern courtesy: tgt %d, src %d, slot %d\n", pattern->courtesy.macid_tgt, pattern->courtesy.macid_src, pattern->courtesy.slot_num); } /* The follow-up roughly shows the relationship between the parameters * for pattern calculation. * * |< duration ref >| (if mid bt) |< duration aux >| * |< tob ref >|< toa ref >| ... |< tob aux >|< toa aux >| * V V * tbtt ref tbtt aux * |< beacon offset >| * * In loose pattern calculation, we only ensure at least tob_ref and * toa_ref have positive results. If tob_aux or toa_aux is negative * unfortunately, FW will be notified to handle it with courtesy * mechanism. */ static void __rtw89_mcc_calc_pattern_loose(struct rtw89_dev *rtwdev, struct rtw89_mcc_pattern *ptrn, bool hdl_bt) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_config *config = &mcc->config; u16 bcn_ofst = config->beacon_offset; u16 bt_dur_in_mid = 0; u16 max_bcn_ofst; s16 upper, lower; u16 res; *ptrn = (typeof(*ptrn)){ .plan = hdl_bt ? RTW89_MCC_PLAN_TAIL_BT : RTW89_MCC_PLAN_NO_BT, }; if (!hdl_bt) goto calc; max_bcn_ofst = ref->duration + aux->duration; if (ref->limit.enable) max_bcn_ofst = min_t(u16, max_bcn_ofst, ref->limit.max_toa + aux->duration); else if (aux->limit.enable) max_bcn_ofst = min_t(u16, max_bcn_ofst, ref->duration + aux->limit.max_tob); if (bcn_ofst > max_bcn_ofst && bcn_ofst >= mcc->bt_role.duration) { bt_dur_in_mid = mcc->bt_role.duration; ptrn->plan = RTW89_MCC_PLAN_MID_BT; } calc: rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_ls: plan %d, bcn_ofst %d\n", ptrn->plan, bcn_ofst); res = bcn_ofst - bt_dur_in_mid; upper = min_t(s16, ref->duration, res); lower = 0; if (ref->limit.enable) { upper = min_t(s16, upper, ref->limit.max_toa); lower = max_t(s16, lower, ref->duration - ref->limit.max_tob); } else if (aux->limit.enable) { upper = min_t(s16, upper, res - (aux->duration - aux->limit.max_toa)); lower = max_t(s16, lower, res - aux->limit.max_tob); } if (lower < upper) ptrn->toa_ref = (upper + lower) / 2; else ptrn->toa_ref = lower; ptrn->tob_ref = ref->duration - ptrn->toa_ref; ptrn->tob_aux = res - ptrn->toa_ref; ptrn->toa_aux = aux->duration - ptrn->tob_aux; } /* In strict pattern calculation, we consider timing that might need * for HW stuffs, i.e. min_tob and min_toa. */ static int __rtw89_mcc_calc_pattern_strict(struct rtw89_dev *rtwdev, struct rtw89_mcc_pattern *ptrn) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_config *config = &mcc->config; u16 min_tob = RTW89_MCC_EARLY_RX_BCN_TIME; u16 min_toa = RTW89_MCC_MIN_RX_BCN_TIME; u16 bcn_ofst = config->beacon_offset; s16 upper_toa_ref, lower_toa_ref; s16 upper_tob_aux, lower_tob_aux; u16 bt_dur_in_mid; s16 res; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st: plan %d, bcn_ofst %d\n", ptrn->plan, bcn_ofst); if (ptrn->plan == RTW89_MCC_PLAN_MID_BT) bt_dur_in_mid = mcc->bt_role.duration; else bt_dur_in_mid = 0; if (ref->duration < min_tob + min_toa) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st: not meet ref dur cond\n"); return -EINVAL; } if (aux->duration < min_tob + min_toa) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st: not meet aux dur cond\n"); return -EINVAL; } res = bcn_ofst - min_toa - min_tob - bt_dur_in_mid; if (res < 0) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st: not meet bcn_ofst cond\n"); return -EINVAL; } upper_toa_ref = min_t(s16, min_toa + res, ref->duration - min_tob); lower_toa_ref = min_toa; upper_tob_aux = min_t(s16, min_tob + res, aux->duration - min_toa); lower_tob_aux = min_tob; if (ref->limit.enable) { if (min_tob > ref->limit.max_tob || min_toa > ref->limit.max_toa) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st: conflict ref limit\n"); return -EINVAL; } upper_toa_ref = min_t(s16, upper_toa_ref, ref->limit.max_toa); lower_toa_ref = max_t(s16, lower_toa_ref, ref->duration - ref->limit.max_tob); } else if (aux->limit.enable) { if (min_tob > aux->limit.max_tob || min_toa > aux->limit.max_toa) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st: conflict aux limit\n"); return -EINVAL; } upper_tob_aux = min_t(s16, upper_tob_aux, aux->limit.max_tob); lower_tob_aux = max_t(s16, lower_tob_aux, aux->duration - aux->limit.max_toa); } upper_toa_ref = min_t(s16, upper_toa_ref, bcn_ofst - bt_dur_in_mid - lower_tob_aux); lower_toa_ref = max_t(s16, lower_toa_ref, bcn_ofst - bt_dur_in_mid - upper_tob_aux); if (lower_toa_ref > upper_toa_ref) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st: conflict boundary\n"); return -EINVAL; } ptrn->toa_ref = (upper_toa_ref + lower_toa_ref) / 2; ptrn->tob_ref = ref->duration - ptrn->toa_ref; ptrn->tob_aux = bcn_ofst - ptrn->toa_ref - bt_dur_in_mid; ptrn->toa_aux = aux->duration - ptrn->tob_aux; return 0; } static int rtw89_mcc_calc_pattern(struct rtw89_dev *rtwdev, bool hdl_bt) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; bool sel_plan[NUM_OF_RTW89_MCC_PLAN] = {}; struct rtw89_mcc_pattern ptrn; int ret; int i; if (ref->limit.enable && aux->limit.enable) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn: not support dual limited roles\n"); return -EINVAL; } if (ref->limit.enable && ref->duration > ref->limit.max_tob + ref->limit.max_toa) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn: not fit ref limit\n"); return -EINVAL; } if (aux->limit.enable && aux->duration > aux->limit.max_tob + aux->limit.max_toa) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn: not fit aux limit\n"); return -EINVAL; } if (hdl_bt) { sel_plan[RTW89_MCC_PLAN_TAIL_BT] = true; sel_plan[RTW89_MCC_PLAN_MID_BT] = true; } else { sel_plan[RTW89_MCC_PLAN_NO_BT] = true; } for (i = 0; i < NUM_OF_RTW89_MCC_PLAN; i++) { if (!sel_plan[i]) continue; ptrn = (typeof(ptrn)){ .plan = i, }; ret = __rtw89_mcc_calc_pattern_strict(rtwdev, &ptrn); if (ret) rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC calc ptrn_st with plan %d: fail\n", i); else goto done; } __rtw89_mcc_calc_pattern_loose(rtwdev, &ptrn, hdl_bt); done: rtw89_mcc_assign_pattern(rtwdev, &ptrn); return 0; } static void rtw89_mcc_set_default_pattern(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_pattern tmp = {}; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC use default pattern unexpectedly\n"); tmp.plan = RTW89_MCC_PLAN_NO_BT; tmp.tob_ref = ref->duration / 2; tmp.toa_ref = ref->duration - tmp.tob_ref; tmp.tob_aux = aux->duration / 2; tmp.toa_aux = aux->duration - tmp.tob_aux; rtw89_mcc_assign_pattern(rtwdev, &tmp); } static void rtw89_mcc_set_duration_go_sta(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *role_go, struct rtw89_mcc_role *role_sta) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; u16 mcc_intvl = config->mcc_interval; u16 dur_go, dur_sta; dur_go = clamp_t(u16, role_go->duration, RTW89_MCC_MIN_GO_DURATION, mcc_intvl - RTW89_MCC_MIN_STA_DURATION); if (role_go->limit.enable) dur_go = min(dur_go, role_go->limit.max_dur); dur_sta = mcc_intvl - dur_go; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC set dur: (go, sta) {%d, %d} -> {%d, %d}\n", role_go->duration, role_sta->duration, dur_go, dur_sta); role_go->duration = dur_go; role_sta->duration = dur_sta; } static void rtw89_mcc_set_duration_gc_sta(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_config *config = &mcc->config; u16 mcc_intvl = config->mcc_interval; u16 dur_ref, dur_aux; if (ref->duration < RTW89_MCC_MIN_STA_DURATION) { dur_ref = RTW89_MCC_MIN_STA_DURATION; dur_aux = mcc_intvl - dur_ref; } else if (aux->duration < RTW89_MCC_MIN_STA_DURATION) { dur_aux = RTW89_MCC_MIN_STA_DURATION; dur_ref = mcc_intvl - dur_aux; } else { dur_ref = ref->duration; dur_aux = mcc_intvl - dur_ref; } if (ref->limit.enable) { dur_ref = min(dur_ref, ref->limit.max_dur); dur_aux = mcc_intvl - dur_ref; } else if (aux->limit.enable) { dur_aux = min(dur_aux, aux->limit.max_dur); dur_ref = mcc_intvl - dur_aux; } rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC set dur: (ref, aux) {%d ~ %d} -> {%d ~ %d}\n", ref->duration, aux->duration, dur_ref, dur_aux); ref->duration = dur_ref; aux->duration = dur_aux; } struct rtw89_mcc_mod_dur_data { u16 available; struct { u16 dur; u16 room; } parm[NUM_OF_RTW89_MCC_ROLES]; }; static int rtw89_mcc_mod_dur_get_iterator(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role, unsigned int ordered_idx, void *data) { struct rtw89_mcc_mod_dur_data *p = data; u16 min; p->parm[ordered_idx].dur = mcc_role->duration; if (mcc_role->is_go) min = RTW89_MCC_MIN_GO_DURATION; else min = RTW89_MCC_MIN_STA_DURATION; p->parm[ordered_idx].room = max_t(s32, p->parm[ordered_idx].dur - min, 0); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur: chk role[%u]: dur %u, min %u, room %u\n", ordered_idx, p->parm[ordered_idx].dur, min, p->parm[ordered_idx].room); p->available += p->parm[ordered_idx].room; return 0; } static int rtw89_mcc_mod_dur_put_iterator(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role, unsigned int ordered_idx, void *data) { struct rtw89_mcc_mod_dur_data *p = data; mcc_role->duration = p->parm[ordered_idx].dur; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur: set role[%u]: dur %u\n", ordered_idx, p->parm[ordered_idx].dur); return 0; } static void rtw89_mcc_mod_duration_dual_2ghz_with_bt(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_mod_dur_data data = {}; u16 mcc_intvl = config->mcc_interval; u16 bt_dur = mcc->bt_role.duration; u16 wifi_dur; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur (dual 2ghz): mcc_intvl %u, raw bt_dur %u\n", mcc_intvl, bt_dur); rtw89_iterate_mcc_roles(rtwdev, rtw89_mcc_mod_dur_get_iterator, &data); bt_dur = clamp_t(u16, bt_dur, 1, data.available / 3); wifi_dur = mcc_intvl - bt_dur; if (data.parm[0].room <= data.parm[1].room) { data.parm[0].dur -= min_t(u16, bt_dur / 2, data.parm[0].room); data.parm[1].dur = wifi_dur - data.parm[0].dur; } else { data.parm[1].dur -= min_t(u16, bt_dur / 2, data.parm[1].room); data.parm[0].dur = wifi_dur - data.parm[1].dur; } rtw89_iterate_mcc_roles(rtwdev, rtw89_mcc_mod_dur_put_iterator, &data); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur: set bt: dur %u\n", bt_dur); mcc->bt_role.duration = bt_dur; } static void rtw89_mcc_mod_duration_diff_band_with_bt(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *role_2ghz, struct rtw89_mcc_role *role_non_2ghz) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; u16 dur_2ghz, dur_non_2ghz; u16 bt_dur, mcc_intvl; dur_2ghz = role_2ghz->duration; dur_non_2ghz = role_non_2ghz->duration; mcc_intvl = config->mcc_interval; bt_dur = mcc->bt_role.duration; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur (diff band): mcc_intvl %u, bt_dur %u\n", mcc_intvl, bt_dur); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur: check dur_2ghz %u, dur_non_2ghz %u\n", dur_2ghz, dur_non_2ghz); if (dur_non_2ghz >= bt_dur) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur: dur_non_2ghz is enough for bt\n"); return; } dur_non_2ghz = bt_dur; dur_2ghz = mcc_intvl - dur_non_2ghz; if (role_non_2ghz->limit.enable) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur: dur_non_2ghz is limited with max %u\n", role_non_2ghz->limit.max_dur); dur_non_2ghz = min(dur_non_2ghz, role_non_2ghz->limit.max_dur); dur_2ghz = mcc_intvl - dur_non_2ghz; } rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC mod dur: set dur_2ghz %u, dur_non_2ghz %u\n", dur_2ghz, dur_non_2ghz); role_2ghz->duration = dur_2ghz; role_non_2ghz->duration = dur_non_2ghz; } static bool rtw89_mcc_duration_decision_on_bt(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_bt_role *bt_role = &mcc->bt_role; if (!bt_role->duration) return false; if (ref->is_2ghz && aux->is_2ghz) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC dual roles are on 2GHz; consider BT duration\n"); rtw89_mcc_mod_duration_dual_2ghz_with_bt(rtwdev); return true; } if (!ref->is_2ghz && !aux->is_2ghz) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC dual roles are not on 2GHz; ignore BT duration\n"); return false; } rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC one role is on 2GHz; modify another for BT duration\n"); if (ref->is_2ghz) rtw89_mcc_mod_duration_diff_band_with_bt(rtwdev, ref, aux); else rtw89_mcc_mod_duration_diff_band_with_bt(rtwdev, aux, ref); return false; } static void rtw89_mcc_sync_tbtt(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *tgt, struct rtw89_mcc_role *src, bool ref_is_src) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; u16 beacon_offset_us = ieee80211_tu_to_usec(config->beacon_offset); u32 bcn_intvl_src_us = ieee80211_tu_to_usec(src->beacon_interval); u32 cur_tbtt_ofst_src; u32 tsf_ofst_tgt; u32 remainder; u64 tbtt_tgt; u64 tsf_src; int ret; ret = rtw89_mac_port_get_tsf(rtwdev, src->rtwvif, &tsf_src); if (ret) { rtw89_warn(rtwdev, "MCC failed to get port tsf: %d\n", ret); return; } cur_tbtt_ofst_src = rtw89_mcc_get_tbtt_ofst(rtwdev, src, tsf_src); if (ref_is_src) tbtt_tgt = tsf_src - cur_tbtt_ofst_src + beacon_offset_us; else tbtt_tgt = tsf_src - cur_tbtt_ofst_src + (bcn_intvl_src_us - beacon_offset_us); div_u64_rem(tbtt_tgt, bcn_intvl_src_us, &remainder); tsf_ofst_tgt = bcn_intvl_src_us - remainder; config->sync.macid_tgt = tgt->rtwvif->mac_id; config->sync.macid_src = src->rtwvif->mac_id; config->sync.offset = tsf_ofst_tgt / 1024; config->sync.enable = true; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC sync tbtt: tgt %d, src %d, offset %d\n", config->sync.macid_tgt, config->sync.macid_src, config->sync.offset); rtw89_mac_port_tsf_sync(rtwdev, tgt->rtwvif, src->rtwvif, config->sync.offset); } static int rtw89_mcc_fill_start_tsf(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_config *config = &mcc->config; u32 bcn_intvl_ref_us = ieee80211_tu_to_usec(ref->beacon_interval); u32 tob_ref_us = ieee80211_tu_to_usec(config->pattern.tob_ref); struct rtw89_vif *rtwvif = ref->rtwvif; u64 tsf, start_tsf; u32 cur_tbtt_ofst; u64 min_time; int ret; ret = rtw89_mac_port_get_tsf(rtwdev, rtwvif, &tsf); if (ret) { rtw89_warn(rtwdev, "MCC failed to get port tsf: %d\n", ret); return ret; } min_time = tsf; if (ref->is_go) min_time += ieee80211_tu_to_usec(RTW89_MCC_SHORT_TRIGGER_TIME); else min_time += ieee80211_tu_to_usec(RTW89_MCC_LONG_TRIGGER_TIME); cur_tbtt_ofst = rtw89_mcc_get_tbtt_ofst(rtwdev, ref, tsf); start_tsf = tsf - cur_tbtt_ofst + bcn_intvl_ref_us - tob_ref_us; while (start_tsf < min_time) start_tsf += bcn_intvl_ref_us; config->start_tsf = start_tsf; return 0; } static int rtw89_mcc_fill_config(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_config *config = &mcc->config; bool hdl_bt; int ret; memset(config, 0, sizeof(*config)); switch (mcc->mode) { case RTW89_MCC_MODE_GO_STA: config->beacon_offset = RTW89_MCC_DFLT_BCN_OFST_TIME; if (ref->is_go) { rtw89_mcc_sync_tbtt(rtwdev, ref, aux, false); config->mcc_interval = ref->beacon_interval; rtw89_mcc_set_duration_go_sta(rtwdev, ref, aux); } else { rtw89_mcc_sync_tbtt(rtwdev, aux, ref, true); config->mcc_interval = aux->beacon_interval; rtw89_mcc_set_duration_go_sta(rtwdev, aux, ref); } break; case RTW89_MCC_MODE_GC_STA: config->beacon_offset = rtw89_mcc_get_bcn_ofst(rtwdev); config->mcc_interval = ref->beacon_interval; rtw89_mcc_set_duration_gc_sta(rtwdev); break; default: rtw89_warn(rtwdev, "MCC unknown mode: %d\n", mcc->mode); return -EFAULT; } hdl_bt = rtw89_mcc_duration_decision_on_bt(rtwdev); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC handle bt: %d\n", hdl_bt); ret = rtw89_mcc_calc_pattern(rtwdev, hdl_bt); if (!ret) goto bottom; rtw89_mcc_set_default_pattern(rtwdev); bottom: return rtw89_mcc_fill_start_tsf(rtwdev); } static int __mcc_fw_add_role(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *role) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_pattern *pattern = &config->pattern; struct rtw89_mcc_courtesy *courtesy = &pattern->courtesy; struct rtw89_mcc_policy *policy = &role->policy; struct rtw89_fw_mcc_add_req req = {}; const struct rtw89_chan *chan; int ret; chan = rtw89_chan_get(rtwdev, role->rtwvif->sub_entity_idx); req.central_ch_seg0 = chan->channel; req.primary_ch = chan->primary_channel; req.bandwidth = chan->band_width; req.ch_band_type = chan->band_type; req.macid = role->rtwvif->mac_id; req.group = mcc->group; req.c2h_rpt = policy->c2h_rpt; req.tx_null_early = policy->tx_null_early; req.dis_tx_null = policy->dis_tx_null; req.in_curr_ch = policy->in_curr_ch; req.sw_retry_count = policy->sw_retry_count; req.dis_sw_retry = policy->dis_sw_retry; req.duration = role->duration; req.btc_in_2g = false; if (courtesy->enable && courtesy->macid_src == req.macid) { req.courtesy_target = courtesy->macid_tgt; req.courtesy_num = courtesy->slot_num; req.courtesy_en = true; } ret = rtw89_fw_h2c_add_mcc(rtwdev, &req); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to add wifi role: %d\n", ret); return ret; } ret = rtw89_fw_h2c_mcc_macid_bitmap(rtwdev, mcc->group, role->rtwvif->mac_id, role->macid_bitmap); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to set macid bitmap: %d\n", ret); return ret; } return 0; } static int __mcc_fw_add_bt_role(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_bt_role *bt_role = &mcc->bt_role; struct rtw89_fw_mcc_add_req req = {}; int ret; req.group = mcc->group; req.duration = bt_role->duration; req.btc_in_2g = true; ret = rtw89_fw_h2c_add_mcc(rtwdev, &req); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to add bt role: %d\n", ret); return ret; } return 0; } static int __mcc_fw_start(struct rtw89_dev *rtwdev, bool replace) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_pattern *pattern = &config->pattern; struct rtw89_mcc_sync *sync = &config->sync; struct rtw89_fw_mcc_start_req req = {}; int ret; if (replace) { req.old_group = mcc->group; req.old_group_action = RTW89_FW_MCC_OLD_GROUP_ACT_REPLACE; mcc->group = RTW89_MCC_NEXT_GROUP(mcc->group); } req.group = mcc->group; switch (pattern->plan) { case RTW89_MCC_PLAN_TAIL_BT: ret = __mcc_fw_add_role(rtwdev, ref); if (ret) return ret; ret = __mcc_fw_add_role(rtwdev, aux); if (ret) return ret; ret = __mcc_fw_add_bt_role(rtwdev); if (ret) return ret; req.btc_in_group = true; break; case RTW89_MCC_PLAN_MID_BT: ret = __mcc_fw_add_role(rtwdev, ref); if (ret) return ret; ret = __mcc_fw_add_bt_role(rtwdev); if (ret) return ret; ret = __mcc_fw_add_role(rtwdev, aux); if (ret) return ret; req.btc_in_group = true; break; case RTW89_MCC_PLAN_NO_BT: ret = __mcc_fw_add_role(rtwdev, ref); if (ret) return ret; ret = __mcc_fw_add_role(rtwdev, aux); if (ret) return ret; req.btc_in_group = false; break; default: rtw89_warn(rtwdev, "MCC unknown plan: %d\n", pattern->plan); return -EFAULT; } if (sync->enable) { ret = rtw89_fw_h2c_mcc_sync(rtwdev, req.group, sync->macid_src, sync->macid_tgt, sync->offset); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to trigger sync: %d\n", ret); return ret; } } req.macid = ref->rtwvif->mac_id; req.tsf_high = config->start_tsf >> 32; req.tsf_low = config->start_tsf; ret = rtw89_fw_h2c_start_mcc(rtwdev, &req); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to trigger start: %d\n", ret); return ret; } return 0; } static int __mcc_fw_set_duration_no_bt(struct rtw89_dev *rtwdev, bool sync_changed) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_sync *sync = &config->sync; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_fw_mcc_duration req = { .group = mcc->group, .btc_in_group = false, .start_macid = ref->rtwvif->mac_id, .macid_x = ref->rtwvif->mac_id, .macid_y = aux->rtwvif->mac_id, .duration_x = ref->duration, .duration_y = aux->duration, .start_tsf_high = config->start_tsf >> 32, .start_tsf_low = config->start_tsf, }; int ret; ret = rtw89_fw_h2c_mcc_set_duration(rtwdev, &req); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to set duration: %d\n", ret); return ret; } if (!sync->enable || !sync_changed) return 0; ret = rtw89_fw_h2c_mcc_sync(rtwdev, mcc->group, sync->macid_src, sync->macid_tgt, sync->offset); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to trigger sync: %d\n", ret); return ret; } return 0; } static void rtw89_mcc_handle_beacon_noa(struct rtw89_dev *rtwdev, bool enable) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_pattern *pattern = &config->pattern; struct rtw89_mcc_sync *sync = &config->sync; struct ieee80211_p2p_noa_desc noa_desc = {}; u64 start_time = config->start_tsf; u32 interval = config->mcc_interval; struct rtw89_vif *rtwvif_go; u32 duration; if (mcc->mode != RTW89_MCC_MODE_GO_STA) return; if (ref->is_go) { rtwvif_go = ref->rtwvif; start_time += ieee80211_tu_to_usec(ref->duration); duration = config->mcc_interval - ref->duration; } else if (aux->is_go) { rtwvif_go = aux->rtwvif; start_time += ieee80211_tu_to_usec(pattern->tob_ref) + ieee80211_tu_to_usec(config->beacon_offset) + ieee80211_tu_to_usec(pattern->toa_aux); duration = config->mcc_interval - aux->duration; /* convert time domain from sta(ref) to GO(aux) */ start_time += ieee80211_tu_to_usec(sync->offset); } else { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC find no GO: skip updating beacon NoA\n"); return; } rtw89_p2p_noa_renew(rtwvif_go); if (enable) { noa_desc.start_time = cpu_to_le32(start_time); noa_desc.interval = cpu_to_le32(ieee80211_tu_to_usec(interval)); noa_desc.duration = cpu_to_le32(ieee80211_tu_to_usec(duration)); noa_desc.count = 255; rtw89_p2p_noa_append(rtwvif_go, &noa_desc); } /* without chanctx, we cannot get beacon from mac80211 stack */ if (!rtwvif_go->chanctx_assigned) return; rtw89_fw_h2c_update_beacon(rtwdev, rtwvif_go); } static void rtw89_mcc_start_beacon_noa(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; if (mcc->mode != RTW89_MCC_MODE_GO_STA) return; if (ref->is_go) rtw89_fw_h2c_tsf32_toggle(rtwdev, ref->rtwvif, true); else if (aux->is_go) rtw89_fw_h2c_tsf32_toggle(rtwdev, aux->rtwvif, true); rtw89_mcc_handle_beacon_noa(rtwdev, true); } static void rtw89_mcc_stop_beacon_noa(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; if (mcc->mode != RTW89_MCC_MODE_GO_STA) return; if (ref->is_go) rtw89_fw_h2c_tsf32_toggle(rtwdev, ref->rtwvif, false); else if (aux->is_go) rtw89_fw_h2c_tsf32_toggle(rtwdev, aux->rtwvif, false); rtw89_mcc_handle_beacon_noa(rtwdev, false); } static int rtw89_mcc_start(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; struct rtw89_mcc_role *aux = &mcc->role_aux; int ret; if (rtwdev->scanning) rtw89_hw_scan_abort(rtwdev, rtwdev->scan_info.scanning_vif); rtw89_leave_lps(rtwdev); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC start\n"); ret = rtw89_mcc_fill_all_roles(rtwdev); if (ret) return ret; if (ref->is_go || aux->is_go) mcc->mode = RTW89_MCC_MODE_GO_STA; else mcc->mode = RTW89_MCC_MODE_GC_STA; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC sel mode: %d\n", mcc->mode); mcc->group = RTW89_MCC_DFLT_GROUP; ret = rtw89_mcc_fill_config(rtwdev); if (ret) return ret; ret = __mcc_fw_start(rtwdev, false); if (ret) return ret; rtw89_chanctx_notify(rtwdev, RTW89_CHANCTX_STATE_MCC_START); rtw89_mcc_start_beacon_noa(rtwdev); return 0; } static void rtw89_mcc_stop(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role *ref = &mcc->role_ref; int ret; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC stop\n"); ret = rtw89_fw_h2c_stop_mcc(rtwdev, mcc->group, ref->rtwvif->mac_id, true); if (ret) rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to trigger stop: %d\n", ret); ret = rtw89_fw_h2c_del_mcc_group(rtwdev, mcc->group, true); if (ret) rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to delete group: %d\n", ret); rtw89_chanctx_notify(rtwdev, RTW89_CHANCTX_STATE_MCC_STOP); rtw89_mcc_stop_beacon_noa(rtwdev); } static int rtw89_mcc_update(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_config old_cfg = *config; bool sync_changed; int ret; if (rtwdev->scanning) rtw89_hw_scan_abort(rtwdev, rtwdev->scan_info.scanning_vif); rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC update\n"); ret = rtw89_mcc_fill_config(rtwdev); if (ret) return ret; if (old_cfg.pattern.plan != RTW89_MCC_PLAN_NO_BT || config->pattern.plan != RTW89_MCC_PLAN_NO_BT) { ret = __mcc_fw_start(rtwdev, true); if (ret) return ret; } else { if (memcmp(&old_cfg.sync, &config->sync, sizeof(old_cfg.sync)) == 0) sync_changed = false; else sync_changed = true; ret = __mcc_fw_set_duration_no_bt(rtwdev, sync_changed); if (ret) return ret; } rtw89_mcc_handle_beacon_noa(rtwdev, true); return 0; } static void rtw89_mcc_track(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_config *config = &mcc->config; struct rtw89_mcc_pattern *pattern = &config->pattern; s16 tolerance; u16 bcn_ofst; u16 diff; if (mcc->mode != RTW89_MCC_MODE_GC_STA) return; bcn_ofst = rtw89_mcc_get_bcn_ofst(rtwdev); if (bcn_ofst > config->beacon_offset) { diff = bcn_ofst - config->beacon_offset; if (pattern->tob_aux < 0) tolerance = -pattern->tob_aux; else tolerance = pattern->toa_aux; } else { diff = config->beacon_offset - bcn_ofst; if (pattern->toa_aux < 0) tolerance = -pattern->toa_aux; else tolerance = pattern->tob_aux; } if (diff <= tolerance) return; rtw89_queue_chanctx_change(rtwdev, RTW89_CHANCTX_BCN_OFFSET_CHANGE); } static int rtw89_mcc_upd_map_iterator(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role, unsigned int ordered_idx, void *data) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; struct rtw89_mcc_role upd = { .rtwvif = mcc_role->rtwvif, }; int ret; if (!mcc_role->is_go) return 0; rtw89_mcc_fill_role_macid_bitmap(rtwdev, &upd); if (memcmp(mcc_role->macid_bitmap, upd.macid_bitmap, sizeof(mcc_role->macid_bitmap)) == 0) return 0; ret = rtw89_fw_h2c_mcc_macid_bitmap(rtwdev, mcc->group, upd.rtwvif->mac_id, upd.macid_bitmap); if (ret) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "MCC h2c failed to update macid bitmap: %d\n", ret); return ret; } memcpy(mcc_role->macid_bitmap, upd.macid_bitmap, sizeof(mcc_role->macid_bitmap)); return 0; } static void rtw89_mcc_update_macid_bitmap(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; if (mcc->mode != RTW89_MCC_MODE_GO_STA) return; rtw89_iterate_mcc_roles(rtwdev, rtw89_mcc_upd_map_iterator, NULL); } static int rtw89_mcc_upd_lmt_iterator(struct rtw89_dev *rtwdev, struct rtw89_mcc_role *mcc_role, unsigned int ordered_idx, void *data) { memset(&mcc_role->limit, 0, sizeof(mcc_role->limit)); rtw89_mcc_fill_role_limit(rtwdev, mcc_role); return 0; } static void rtw89_mcc_update_limit(struct rtw89_dev *rtwdev) { struct rtw89_mcc_info *mcc = &rtwdev->mcc; if (mcc->mode != RTW89_MCC_MODE_GC_STA) return; rtw89_iterate_mcc_roles(rtwdev, rtw89_mcc_upd_lmt_iterator, NULL); } void rtw89_chanctx_work(struct work_struct *work) { struct rtw89_dev *rtwdev = container_of(work, struct rtw89_dev, chanctx_work.work); struct rtw89_hal *hal = &rtwdev->hal; bool update_mcc_pattern = false; enum rtw89_entity_mode mode; u32 changed = 0; int ret; int i; mutex_lock(&rtwdev->mutex); if (hal->entity_pause) { mutex_unlock(&rtwdev->mutex); return; } for (i = 0; i < NUM_OF_RTW89_CHANCTX_CHANGES; i++) { if (test_and_clear_bit(i, hal->changes)) changed |= BIT(i); } mode = rtw89_get_entity_mode(rtwdev); switch (mode) { case RTW89_ENTITY_MODE_MCC_PREPARE: rtw89_set_entity_mode(rtwdev, RTW89_ENTITY_MODE_MCC); rtw89_set_channel(rtwdev); ret = rtw89_mcc_start(rtwdev); if (ret) rtw89_warn(rtwdev, "failed to start MCC: %d\n", ret); break; case RTW89_ENTITY_MODE_MCC: if (changed & BIT(RTW89_CHANCTX_BCN_OFFSET_CHANGE) || changed & BIT(RTW89_CHANCTX_P2P_PS_CHANGE) || changed & BIT(RTW89_CHANCTX_BT_SLOT_CHANGE) || changed & BIT(RTW89_CHANCTX_TSF32_TOGGLE_CHANGE)) update_mcc_pattern = true; if (changed & BIT(RTW89_CHANCTX_REMOTE_STA_CHANGE)) rtw89_mcc_update_macid_bitmap(rtwdev); if (changed & BIT(RTW89_CHANCTX_P2P_PS_CHANGE)) rtw89_mcc_update_limit(rtwdev); if (changed & BIT(RTW89_CHANCTX_BT_SLOT_CHANGE)) rtw89_mcc_fill_bt_role(rtwdev); if (update_mcc_pattern) { ret = rtw89_mcc_update(rtwdev); if (ret) rtw89_warn(rtwdev, "failed to update MCC: %d\n", ret); } break; default: break; } mutex_unlock(&rtwdev->mutex); } void rtw89_queue_chanctx_change(struct rtw89_dev *rtwdev, enum rtw89_chanctx_changes change) { struct rtw89_hal *hal = &rtwdev->hal; enum rtw89_entity_mode mode; u32 delay; mode = rtw89_get_entity_mode(rtwdev); switch (mode) { default: return; case RTW89_ENTITY_MODE_MCC_PREPARE: delay = ieee80211_tu_to_usec(RTW89_CHANCTX_TIME_MCC_PREPARE); break; case RTW89_ENTITY_MODE_MCC: delay = ieee80211_tu_to_usec(RTW89_CHANCTX_TIME_MCC); break; } if (change != RTW89_CHANCTX_CHANGE_DFLT) { rtw89_debug(rtwdev, RTW89_DBG_CHAN, "set chanctx change %d\n", change); set_bit(change, hal->changes); } rtw89_debug(rtwdev, RTW89_DBG_CHAN, "queue chanctx work for mode %d with delay %d us\n", mode, delay); ieee80211_queue_delayed_work(rtwdev->hw, &rtwdev->chanctx_work, usecs_to_jiffies(delay)); } void rtw89_queue_chanctx_work(struct rtw89_dev *rtwdev) { rtw89_queue_chanctx_change(rtwdev, RTW89_CHANCTX_CHANGE_DFLT); } void rtw89_chanctx_track(struct rtw89_dev *rtwdev) { struct rtw89_hal *hal = &rtwdev->hal; enum rtw89_entity_mode mode; lockdep_assert_held(&rtwdev->mutex); if (hal->entity_pause) return; mode = rtw89_get_entity_mode(rtwdev); switch (mode) { case RTW89_ENTITY_MODE_MCC: rtw89_mcc_track(rtwdev); break; default: break; } } void rtw89_chanctx_pause(struct rtw89_dev *rtwdev, enum rtw89_chanctx_pause_reasons rsn) { struct rtw89_hal *hal = &rtwdev->hal; enum rtw89_entity_mode mode; lockdep_assert_held(&rtwdev->mutex); if (hal->entity_pause) return; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "chanctx pause (rsn: %d)\n", rsn); mode = rtw89_get_entity_mode(rtwdev); switch (mode) { case RTW89_ENTITY_MODE_MCC: rtw89_mcc_stop(rtwdev); break; default: break; } hal->entity_pause = true; } void rtw89_chanctx_proceed(struct rtw89_dev *rtwdev) { struct rtw89_hal *hal = &rtwdev->hal; enum rtw89_entity_mode mode; int ret; lockdep_assert_held(&rtwdev->mutex); if (!hal->entity_pause) return; rtw89_debug(rtwdev, RTW89_DBG_CHAN, "chanctx proceed\n"); hal->entity_pause = false; rtw89_set_channel(rtwdev); mode = rtw89_get_entity_mode(rtwdev); switch (mode) { case RTW89_ENTITY_MODE_MCC: ret = rtw89_mcc_start(rtwdev); if (ret) rtw89_warn(rtwdev, "failed to start MCC: %d\n", ret); break; default: break; } rtw89_queue_chanctx_work(rtwdev); } int rtw89_chanctx_ops_add(struct rtw89_dev *rtwdev, struct ieee80211_chanctx_conf *ctx) { struct rtw89_hal *hal = &rtwdev->hal; struct rtw89_chanctx_cfg *cfg = (struct rtw89_chanctx_cfg *)ctx->drv_priv; const struct rtw89_chip_info *chip = rtwdev->chip; u8 idx; idx = find_first_zero_bit(hal->entity_map, NUM_OF_RTW89_SUB_ENTITY); if (idx >= chip->support_chanctx_num) return -ENOENT; rtw89_config_entity_chandef(rtwdev, idx, &ctx->def); rtw89_set_channel(rtwdev); cfg->idx = idx; hal->sub[idx].cfg = cfg; return 0; } void rtw89_chanctx_ops_remove(struct rtw89_dev *rtwdev, struct ieee80211_chanctx_conf *ctx) { struct rtw89_hal *hal = &rtwdev->hal; struct rtw89_chanctx_cfg *cfg = (struct rtw89_chanctx_cfg *)ctx->drv_priv; enum rtw89_entity_mode mode; struct rtw89_vif *rtwvif; u8 drop, roll; drop = cfg->idx; if (drop != RTW89_SUB_ENTITY_0) goto out; roll = find_next_bit(hal->entity_map, NUM_OF_RTW89_SUB_ENTITY, drop + 1); /* Follow rtw89_config_default_chandef() when rtw89_entity_recalc(). */ if (roll == NUM_OF_RTW89_SUB_ENTITY) goto out; /* RTW89_SUB_ENTITY_0 is going to release, and another exists. * Make another roll down to RTW89_SUB_ENTITY_0 to replace. */ hal->sub[roll].cfg->idx = RTW89_SUB_ENTITY_0; hal->sub[RTW89_SUB_ENTITY_0] = hal->sub[roll]; rtw89_for_each_rtwvif(rtwdev, rtwvif) { if (rtwvif->sub_entity_idx == roll) rtwvif->sub_entity_idx = RTW89_SUB_ENTITY_0; } atomic_cmpxchg(&hal->roc_entity_idx, roll, RTW89_SUB_ENTITY_0); drop = roll; out: mode = rtw89_get_entity_mode(rtwdev); switch (mode) { case RTW89_ENTITY_MODE_MCC: rtw89_mcc_stop(rtwdev); break; default: break; } clear_bit(drop, hal->entity_map); rtw89_set_channel(rtwdev); } void rtw89_chanctx_ops_change(struct rtw89_dev *rtwdev, struct ieee80211_chanctx_conf *ctx, u32 changed) { struct rtw89_chanctx_cfg *cfg = (struct rtw89_chanctx_cfg *)ctx->drv_priv; u8 idx = cfg->idx; if (changed & IEEE80211_CHANCTX_CHANGE_WIDTH) { rtw89_config_entity_chandef(rtwdev, idx, &ctx->def); rtw89_set_channel(rtwdev); } } int rtw89_chanctx_ops_assign_vif(struct rtw89_dev *rtwdev, struct rtw89_vif *rtwvif, struct ieee80211_chanctx_conf *ctx) { struct rtw89_chanctx_cfg *cfg = (struct rtw89_chanctx_cfg *)ctx->drv_priv; rtwvif->sub_entity_idx = cfg->idx; rtwvif->chanctx_assigned = true; return 0; } void rtw89_chanctx_ops_unassign_vif(struct rtw89_dev *rtwdev, struct rtw89_vif *rtwvif, struct ieee80211_chanctx_conf *ctx) { rtwvif->sub_entity_idx = RTW89_SUB_ENTITY_0; rtwvif->chanctx_assigned = false; }
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