drivers/staging/wfx/hif_tx_mib.h - linux/kernel/git/bpf/bpf - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-only */
 /*
  * Implementation of host-to-chip MIBs of WFxxx Split Mac (WSM) API.
  *
  * Copyright (c) 2017-2019, Silicon Laboratories, Inc.
  * Copyright (c) 2010, ST-Ericsson
  * Copyright (C) 2010, ST-Ericsson SA
  */
 #ifndef WFX_HIF_TX_MIB_H
 #define WFX_HIF_TX_MIB_H

 #include <linux/etherdevice.h>

 #include "wfx.h"
 #include "hif_tx.h"
 #include "hif_api_mib.h"

 static inline int hif_set_output_power(struct wfx_vif *wvif, int val)
 {
 	struct hif_mib_current_tx_power_level arg = {
 		.power_level = cpu_to_le32(val * 10),
 	};

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_CURRENT_TX_POWER_LEVEL,
 			     &arg, sizeof(arg));
 }

 static inline int hif_set_beacon_wakeup_period(struct wfx_vif *wvif,
 					       unsigned int dtim_interval,
 					       unsigned int listen_interval)
 {
 	struct hif_mib_beacon_wake_up_period val = {
 		.wakeup_period_min = dtim_interval,
 		.receive_dtim = 0,
 		.wakeup_period_max = cpu_to_le16(listen_interval),
 	};

 	if (dtim_interval > 0xFF || listen_interval > 0xFFFF)
 		return -EINVAL;
 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_BEACON_WAKEUP_PERIOD,
 			     &val, sizeof(val));
 }

 static inline int hif_set_rcpi_rssi_threshold(struct wfx_vif *wvif,
 					      int rssi_thold, int rssi_hyst)
 {
 	struct hif_mib_rcpi_rssi_threshold arg = {
 		.rolling_average_count = 8,
 		.detection = 1,
 	};

 	if (!rssi_thold && !rssi_hyst) {
 		arg.upperthresh = 1;
 		arg.lowerthresh = 1;
 	} else {
 		arg.upper_threshold = rssi_thold + rssi_hyst;
 		arg.upper_threshold = (arg.upper_threshold + 110) * 2;
 		arg.lower_threshold = rssi_thold;
 		arg.lower_threshold = (arg.lower_threshold + 110) * 2;
 	}

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_RCPI_RSSI_THRESHOLD, &arg, sizeof(arg));
 }

 static inline int hif_get_counters_table(struct wfx_dev *wdev,
 					 struct hif_mib_extended_count_table *arg)
 {
 	if (wfx_api_older_than(wdev, 1, 3)) {
 		// extended_count_table is wider than count_table
 		memset(arg, 0xFF, sizeof(*arg));
 		return hif_read_mib(wdev, 0, HIF_MIB_ID_COUNTERS_TABLE,
 				    arg, sizeof(struct hif_mib_count_table));
 	} else {
 		return hif_read_mib(wdev, 0,
 				    HIF_MIB_ID_EXTENDED_COUNTERS_TABLE, arg,
 				sizeof(struct hif_mib_extended_count_table));
 	}
 }

 static inline int hif_set_macaddr(struct wfx_vif *wvif, u8 *mac)
 {
 	struct hif_mib_mac_address msg = { };

 	if (mac)
 		ether_addr_copy(msg.mac_addr, mac);
 	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_DOT11_MAC_ADDRESS,
 			     &msg, sizeof(msg));
 }

 static inline int hif_set_rx_filter(struct wfx_vif *wvif, bool filter_bssid,
 				    bool fwd_probe_req)
 {
 	struct hif_mib_rx_filter val = { };

 	if (filter_bssid)
 		val.bssid_filter = 1;
 	if (fwd_probe_req)
 		val.fwd_probe_req = 1;
 	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_RX_FILTER,
 			     &val, sizeof(val));
 }

 static inline int hif_set_beacon_filter_table(struct wfx_vif *wvif,
 					      int tbl_len,
 					      struct hif_ie_table_entry *tbl)
 {
 	int ret;
 	struct hif_mib_bcn_filter_table *val;
 	int buf_len = struct_size(val, ie_table, tbl_len);

 	val = kzalloc(buf_len, GFP_KERNEL);
 	if (!val)
 		return -ENOMEM;
 	val->num_of_info_elmts = cpu_to_le32(tbl_len);
 	memcpy(val->ie_table, tbl, tbl_len * sizeof(*tbl));
 	ret = hif_write_mib(wvif->wdev, wvif->id,
 			    HIF_MIB_ID_BEACON_FILTER_TABLE, val, buf_len);
 	kfree(val);
 	return ret;
 }

 static inline int hif_beacon_filter_control(struct wfx_vif *wvif,
 					    int enable, int beacon_count)
 {
 	struct hif_mib_bcn_filter_enable arg = {
 		.enable = cpu_to_le32(enable),
 		.bcn_count = cpu_to_le32(beacon_count),
 	};
 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_BEACON_FILTER_ENABLE,
 			     &arg, sizeof(arg));
 }

 static inline int hif_set_operational_mode(struct wfx_dev *wdev,
 					   enum hif_op_power_mode mode)
 {
 	struct hif_mib_gl_operational_power_mode val = {
 		.power_mode = mode,
 		.wup_ind_activation = 1,
 	};

 	return hif_write_mib(wdev, -1, HIF_MIB_ID_GL_OPERATIONAL_POWER_MODE,
 			     &val, sizeof(val));
 }

 static inline int hif_set_template_frame(struct wfx_vif *wvif,
 					 struct sk_buff *skb,
 					 u8 frame_type, int init_rate)
 {
 	struct hif_mib_template_frame *arg;

 	skb_push(skb, 4);
 	arg = (struct hif_mib_template_frame *)skb->data;
 	skb_pull(skb, 4);
 	arg->init_rate = init_rate;
 	arg->frame_type = frame_type;
 	arg->frame_length = cpu_to_le16(skb->len);
 	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_TEMPLATE_FRAME,
 			     arg, sizeof(*arg));
 }

 static inline int hif_set_mfp(struct wfx_vif *wvif, bool capable, bool required)
 {
 	struct hif_mib_protected_mgmt_policy val = { };

 	WARN(required && !capable, "incoherent arguments");
 	if (capable) {
 		val.pmf_enable = 1;
 		val.host_enc_auth_frames = 1;
 	}
 	if (!required)
 		val.unpmf_allowed = 1;
 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_PROTECTED_MGMT_POLICY,
 			     &val, sizeof(val));
 }

 static inline int hif_set_block_ack_policy(struct wfx_vif *wvif,
 					   u8 tx_tid_policy, u8 rx_tid_policy)
 {
 	struct hif_mib_block_ack_policy val = {
 		.block_ack_tx_tid_policy = tx_tid_policy,
 		.block_ack_rx_tid_policy = rx_tid_policy,
 	};

 	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_BLOCK_ACK_POLICY,
 			     &val, sizeof(val));
 }

 static inline int hif_set_association_mode(struct wfx_vif *wvif,
 					   struct ieee80211_bss_conf *info,
 					   struct ieee80211_sta_ht_cap *ht_cap)
 {
 	int basic_rates = wfx_rate_mask_to_hw(wvif->wdev, info->basic_rates);
 	struct hif_mib_set_association_mode val = {
 		.preambtype_use = 1,
 		.mode = 1,
 		.rateset = 1,
 		.spacing = 1,
 		.short_preamble = info->use_short_preamble,
 		.basic_rate_set = cpu_to_le32(basic_rates)
 	};

 	// FIXME: it is strange to not retrieve all information from bss_info
 	if (ht_cap && ht_cap->ht_supported) {
 		val.mpdu_start_spacing = ht_cap->ampdu_density;
 		if (!(info->ht_operation_mode & IEEE80211_HT_OP_MODE_NON_GF_STA_PRSNT))
 			val.greenfield = !!(ht_cap->cap & IEEE80211_HT_CAP_GRN_FLD);
 	}

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_SET_ASSOCIATION_MODE, &val, sizeof(val));
 }

 static inline int hif_set_tx_rate_retry_policy(struct wfx_vif *wvif,
 					       int policy_index, uint8_t *rates)
 {
 	struct hif_mib_set_tx_rate_retry_policy *arg;
 	size_t size = struct_size(arg, tx_rate_retry_policy, 1);
 	int ret;

 	arg = kzalloc(size, GFP_KERNEL);
 	arg->num_tx_rate_policies = 1;
 	arg->tx_rate_retry_policy[0].policy_index = policy_index;
 	arg->tx_rate_retry_policy[0].short_retry_count = 255;
 	arg->tx_rate_retry_policy[0].long_retry_count = 255;
 	arg->tx_rate_retry_policy[0].first_rate_sel = 1;
 	arg->tx_rate_retry_policy[0].terminate = 1;
 	arg->tx_rate_retry_policy[0].count_init = 1;
 	memcpy(&arg->tx_rate_retry_policy[0].rates, rates,
 	       sizeof(arg->tx_rate_retry_policy[0].rates));
 	ret = hif_write_mib(wvif->wdev, wvif->id,
 			    HIF_MIB_ID_SET_TX_RATE_RETRY_POLICY, arg, size);
 	kfree(arg);
 	return ret;
 }

 static inline int hif_set_mac_addr_condition(struct wfx_vif *wvif,
 					     int idx, const u8 *mac_addr)
 {
 	struct hif_mib_mac_addr_data_frame_condition val = {
 		.condition_idx = idx,
 		.address_type = HIF_MAC_ADDR_A1,
 	};

 	ether_addr_copy(val.mac_address, mac_addr);
 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_MAC_ADDR_DATAFRAME_CONDITION,
 			     &val, sizeof(val));
 }

 static inline int hif_set_uc_mc_bc_condition(struct wfx_vif *wvif,
 					     int idx, u8 allowed_frames)
 {
 	struct hif_mib_uc_mc_bc_data_frame_condition val = {
 		.condition_idx = idx,
 		.allowed_frames = allowed_frames,
 	};

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_UC_MC_BC_DATAFRAME_CONDITION,
 			     &val, sizeof(val));
 }

 static inline int hif_set_config_data_filter(struct wfx_vif *wvif, bool enable,
 					     int idx, int mac_filters,
 					     int frames_types_filters)
 {
 	struct hif_mib_config_data_filter val = {
 		.enable = enable,
 		.filter_idx = idx,
 		.mac_cond = mac_filters,
 		.uc_mc_bc_cond = frames_types_filters,
 	};

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_CONFIG_DATA_FILTER, &val, sizeof(val));
 }

 static inline int hif_set_data_filtering(struct wfx_vif *wvif,
 					 bool enable, bool invert)
 {
 	struct hif_mib_set_data_filtering val = {
 		.enable = enable,
 		.invert_matching = invert,
 	};

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_SET_DATA_FILTERING, &val, sizeof(val));
 }

 static inline int hif_keep_alive_period(struct wfx_vif *wvif, int period)
 {
 	struct hif_mib_keep_alive_period arg = {
 		.keep_alive_period = cpu_to_le16(period),
 	};

 	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_KEEP_ALIVE_PERIOD,
 			     &arg, sizeof(arg));
 };

 static inline int hif_set_arp_ipv4_filter(struct wfx_vif *wvif, int idx,
 					  __be32 *addr)
 {
 	struct hif_mib_arp_ip_addr_table arg = {
 		.condition_idx = idx,
 		.arp_enable = HIF_ARP_NS_FILTERING_DISABLE,
 	};

 	if (addr) {
 		// Caution: type of addr is __be32
 		memcpy(arg.ipv4_address, addr, sizeof(arg.ipv4_address));
 		arg.arp_enable = HIF_ARP_NS_FILTERING_ENABLE;
 	}
 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_ARP_IP_ADDRESSES_TABLE,
 			     &arg, sizeof(arg));
 }

 static inline int hif_use_multi_tx_conf(struct wfx_dev *wdev, bool enable)
 {
 	struct hif_mib_gl_set_multi_msg arg = {
 		.enable_multi_tx_conf = enable,
 	};

 	return hif_write_mib(wdev, -1, HIF_MIB_ID_GL_SET_MULTI_MSG,
 			     &arg, sizeof(arg));
 }

 static inline int hif_set_uapsd_info(struct wfx_vif *wvif, unsigned long val)
 {
 	struct hif_mib_set_uapsd_information arg = { };

 	if (val & BIT(IEEE80211_AC_VO))
 		arg.trig_voice = 1;
 	if (val & BIT(IEEE80211_AC_VI))
 		arg.trig_video = 1;
 	if (val & BIT(IEEE80211_AC_BE))
 		arg.trig_be = 1;
 	if (val & BIT(IEEE80211_AC_BK))
 		arg.trig_bckgrnd = 1;
 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_SET_UAPSD_INFORMATION,
 			     &arg, sizeof(arg));
 }

 static inline int hif_erp_use_protection(struct wfx_vif *wvif, bool enable)
 {
 	struct hif_mib_non_erp_protection arg = {
 		.use_cts_to_self = enable,
 	};

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_NON_ERP_PROTECTION, &arg, sizeof(arg));
 }

 static inline int hif_slot_time(struct wfx_vif *wvif, int val)
 {
 	struct hif_mib_slot_time arg = {
 		.slot_time = cpu_to_le32(val),
 	};

 	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_SLOT_TIME,
 			     &arg, sizeof(arg));
 }

 static inline int hif_dual_cts_protection(struct wfx_vif *wvif, bool enable)
 {
 	struct hif_mib_set_ht_protection arg = {
 		.dual_cts_prot = enable,
 	};

 	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_SET_HT_PROTECTION,
 			     &arg, sizeof(arg));
 }

 static inline int hif_wep_default_key_id(struct wfx_vif *wvif, int val)
 {
 	struct hif_mib_wep_default_key_id arg = {
 		.wep_default_key_id = val,
 	};

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_DOT11_WEP_DEFAULT_KEY_ID,
 			     &arg, sizeof(arg));
 }

 static inline int hif_rts_threshold(struct wfx_vif *wvif, int val)
 {
 	struct hif_mib_dot11_rts_threshold arg = {
 		.threshold = cpu_to_le32(val >= 0 ? val : 0xFFFF),
 	};

 	return hif_write_mib(wvif->wdev, wvif->id,
 			     HIF_MIB_ID_DOT11_RTS_THRESHOLD, &arg, sizeof(arg));
 }

 #endif
	/* SPDX-License-Identifier: GPL-2.0-only */
	/*
	* Implementation of host-to-chip MIBs of WFxxx Split Mac (WSM) API.
	*
	* Copyright (c) 2017-2019, Silicon Laboratories, Inc.
	* Copyright (c) 2010, ST-Ericsson
	* Copyright (C) 2010, ST-Ericsson SA
	*/
	#ifndef WFX_HIF_TX_MIB_H
	#define WFX_HIF_TX_MIB_H

	#include <linux/etherdevice.h>

	#include "wfx.h"
	#include "hif_tx.h"
	#include "hif_api_mib.h"

	static inline int hif_set_output_power(struct wfx_vif *wvif, int val)
	{
	struct hif_mib_current_tx_power_level arg = {
	.power_level = cpu_to_le32(val * 10),
	};

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_CURRENT_TX_POWER_LEVEL,
	&arg, sizeof(arg));
	}

	static inline int hif_set_beacon_wakeup_period(struct wfx_vif *wvif,
	unsigned int dtim_interval,
	unsigned int listen_interval)
	{
	struct hif_mib_beacon_wake_up_period val = {
	.wakeup_period_min = dtim_interval,
	.receive_dtim = 0,
	.wakeup_period_max = cpu_to_le16(listen_interval),
	};

	if (dtim_interval > 0xFF \|\| listen_interval > 0xFFFF)
	return -EINVAL;
	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_BEACON_WAKEUP_PERIOD,
	&val, sizeof(val));
	}

	static inline int hif_set_rcpi_rssi_threshold(struct wfx_vif *wvif,
	int rssi_thold, int rssi_hyst)
	{
	struct hif_mib_rcpi_rssi_threshold arg = {
	.rolling_average_count = 8,
	.detection = 1,
	};

	if (!rssi_thold && !rssi_hyst) {
	arg.upperthresh = 1;
	arg.lowerthresh = 1;
	} else {
	arg.upper_threshold = rssi_thold + rssi_hyst;
	arg.upper_threshold = (arg.upper_threshold + 110) * 2;
	arg.lower_threshold = rssi_thold;
	arg.lower_threshold = (arg.lower_threshold + 110) * 2;
	}

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_RCPI_RSSI_THRESHOLD, &arg, sizeof(arg));
	}

	static inline int hif_get_counters_table(struct wfx_dev *wdev,
	struct hif_mib_extended_count_table *arg)
	{
	if (wfx_api_older_than(wdev, 1, 3)) {
	// extended_count_table is wider than count_table
	memset(arg, 0xFF, sizeof(*arg));
	return hif_read_mib(wdev, 0, HIF_MIB_ID_COUNTERS_TABLE,
	arg, sizeof(struct hif_mib_count_table));
	} else {
	return hif_read_mib(wdev, 0,
	HIF_MIB_ID_EXTENDED_COUNTERS_TABLE, arg,
	sizeof(struct hif_mib_extended_count_table));
	}
	}

	static inline int hif_set_macaddr(struct wfx_vif wvif, u8 mac)
	{
	struct hif_mib_mac_address msg = { };

	if (mac)
	ether_addr_copy(msg.mac_addr, mac);
	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_DOT11_MAC_ADDRESS,
	&msg, sizeof(msg));
	}

	static inline int hif_set_rx_filter(struct wfx_vif *wvif, bool filter_bssid,
	bool fwd_probe_req)
	{
	struct hif_mib_rx_filter val = { };

	if (filter_bssid)
	val.bssid_filter = 1;
	if (fwd_probe_req)
	val.fwd_probe_req = 1;
	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_RX_FILTER,
	&val, sizeof(val));
	}

	static inline int hif_set_beacon_filter_table(struct wfx_vif *wvif,
	int tbl_len,
	struct hif_ie_table_entry *tbl)
	{
	int ret;
	struct hif_mib_bcn_filter_table *val;
	int buf_len = struct_size(val, ie_table, tbl_len);

	val = kzalloc(buf_len, GFP_KERNEL);
	if (!val)
	return -ENOMEM;
	val->num_of_info_elmts = cpu_to_le32(tbl_len);
	memcpy(val->ie_table, tbl, tbl_len * sizeof(*tbl));
	ret = hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_BEACON_FILTER_TABLE, val, buf_len);
	kfree(val);
	return ret;
	}

	static inline int hif_beacon_filter_control(struct wfx_vif *wvif,
	int enable, int beacon_count)
	{
	struct hif_mib_bcn_filter_enable arg = {
	.enable = cpu_to_le32(enable),
	.bcn_count = cpu_to_le32(beacon_count),
	};
	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_BEACON_FILTER_ENABLE,
	&arg, sizeof(arg));
	}

	static inline int hif_set_operational_mode(struct wfx_dev *wdev,
	enum hif_op_power_mode mode)
	{
	struct hif_mib_gl_operational_power_mode val = {
	.power_mode = mode,
	.wup_ind_activation = 1,
	};

	return hif_write_mib(wdev, -1, HIF_MIB_ID_GL_OPERATIONAL_POWER_MODE,
	&val, sizeof(val));
	}

	static inline int hif_set_template_frame(struct wfx_vif *wvif,
	struct sk_buff *skb,
	u8 frame_type, int init_rate)
	{
	struct hif_mib_template_frame *arg;

	skb_push(skb, 4);
	arg = (struct hif_mib_template_frame *)skb->data;
	skb_pull(skb, 4);
	arg->init_rate = init_rate;
	arg->frame_type = frame_type;
	arg->frame_length = cpu_to_le16(skb->len);
	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_TEMPLATE_FRAME,
	arg, sizeof(*arg));
	}

	static inline int hif_set_mfp(struct wfx_vif *wvif, bool capable, bool required)
	{
	struct hif_mib_protected_mgmt_policy val = { };

	WARN(required && !capable, "incoherent arguments");
	if (capable) {
	val.pmf_enable = 1;
	val.host_enc_auth_frames = 1;
	}
	if (!required)
	val.unpmf_allowed = 1;
	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_PROTECTED_MGMT_POLICY,
	&val, sizeof(val));
	}

	static inline int hif_set_block_ack_policy(struct wfx_vif *wvif,
	u8 tx_tid_policy, u8 rx_tid_policy)
	{
	struct hif_mib_block_ack_policy val = {
	.block_ack_tx_tid_policy = tx_tid_policy,
	.block_ack_rx_tid_policy = rx_tid_policy,
	};

	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_BLOCK_ACK_POLICY,
	&val, sizeof(val));
	}

	static inline int hif_set_association_mode(struct wfx_vif *wvif,
	struct ieee80211_bss_conf *info,
	struct ieee80211_sta_ht_cap *ht_cap)
	{
	int basic_rates = wfx_rate_mask_to_hw(wvif->wdev, info->basic_rates);
	struct hif_mib_set_association_mode val = {
	.preambtype_use = 1,
	.mode = 1,
	.rateset = 1,
	.spacing = 1,
	.short_preamble = info->use_short_preamble,
	.basic_rate_set = cpu_to_le32(basic_rates)
	};

	// FIXME: it is strange to not retrieve all information from bss_info
	if (ht_cap && ht_cap->ht_supported) {
	val.mpdu_start_spacing = ht_cap->ampdu_density;
	if (!(info->ht_operation_mode & IEEE80211_HT_OP_MODE_NON_GF_STA_PRSNT))
	val.greenfield = !!(ht_cap->cap & IEEE80211_HT_CAP_GRN_FLD);
	}

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_SET_ASSOCIATION_MODE, &val, sizeof(val));
	}

	static inline int hif_set_tx_rate_retry_policy(struct wfx_vif *wvif,
	int policy_index, uint8_t *rates)
	{
	struct hif_mib_set_tx_rate_retry_policy *arg;
	size_t size = struct_size(arg, tx_rate_retry_policy, 1);
	int ret;

	arg = kzalloc(size, GFP_KERNEL);
	arg->num_tx_rate_policies = 1;
	arg->tx_rate_retry_policy[0].policy_index = policy_index;
	arg->tx_rate_retry_policy[0].short_retry_count = 255;
	arg->tx_rate_retry_policy[0].long_retry_count = 255;
	arg->tx_rate_retry_policy[0].first_rate_sel = 1;
	arg->tx_rate_retry_policy[0].terminate = 1;
	arg->tx_rate_retry_policy[0].count_init = 1;
	memcpy(&arg->tx_rate_retry_policy[0].rates, rates,
	sizeof(arg->tx_rate_retry_policy[0].rates));
	ret = hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_SET_TX_RATE_RETRY_POLICY, arg, size);
	kfree(arg);
	return ret;
	}

	static inline int hif_set_mac_addr_condition(struct wfx_vif *wvif,
	int idx, const u8 *mac_addr)
	{
	struct hif_mib_mac_addr_data_frame_condition val = {
	.condition_idx = idx,
	.address_type = HIF_MAC_ADDR_A1,
	};

	ether_addr_copy(val.mac_address, mac_addr);
	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_MAC_ADDR_DATAFRAME_CONDITION,
	&val, sizeof(val));
	}

	static inline int hif_set_uc_mc_bc_condition(struct wfx_vif *wvif,
	int idx, u8 allowed_frames)
	{
	struct hif_mib_uc_mc_bc_data_frame_condition val = {
	.condition_idx = idx,
	.allowed_frames = allowed_frames,
	};

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_UC_MC_BC_DATAFRAME_CONDITION,
	&val, sizeof(val));
	}

	static inline int hif_set_config_data_filter(struct wfx_vif *wvif, bool enable,
	int idx, int mac_filters,
	int frames_types_filters)
	{
	struct hif_mib_config_data_filter val = {
	.enable = enable,
	.filter_idx = idx,
	.mac_cond = mac_filters,
	.uc_mc_bc_cond = frames_types_filters,
	};

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_CONFIG_DATA_FILTER, &val, sizeof(val));
	}

	static inline int hif_set_data_filtering(struct wfx_vif *wvif,
	bool enable, bool invert)
	{
	struct hif_mib_set_data_filtering val = {
	.enable = enable,
	.invert_matching = invert,
	};

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_SET_DATA_FILTERING, &val, sizeof(val));
	}

	static inline int hif_keep_alive_period(struct wfx_vif *wvif, int period)
	{
	struct hif_mib_keep_alive_period arg = {
	.keep_alive_period = cpu_to_le16(period),
	};

	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_KEEP_ALIVE_PERIOD,
	&arg, sizeof(arg));
	};

	static inline int hif_set_arp_ipv4_filter(struct wfx_vif *wvif, int idx,
	__be32 *addr)
	{
	struct hif_mib_arp_ip_addr_table arg = {
	.condition_idx = idx,
	.arp_enable = HIF_ARP_NS_FILTERING_DISABLE,
	};

	if (addr) {
	// Caution: type of addr is __be32
	memcpy(arg.ipv4_address, addr, sizeof(arg.ipv4_address));
	arg.arp_enable = HIF_ARP_NS_FILTERING_ENABLE;
	}
	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_ARP_IP_ADDRESSES_TABLE,
	&arg, sizeof(arg));
	}

	static inline int hif_use_multi_tx_conf(struct wfx_dev *wdev, bool enable)
	{
	struct hif_mib_gl_set_multi_msg arg = {
	.enable_multi_tx_conf = enable,
	};

	return hif_write_mib(wdev, -1, HIF_MIB_ID_GL_SET_MULTI_MSG,
	&arg, sizeof(arg));
	}

	static inline int hif_set_uapsd_info(struct wfx_vif *wvif, unsigned long val)
	{
	struct hif_mib_set_uapsd_information arg = { };

	if (val & BIT(IEEE80211_AC_VO))
	arg.trig_voice = 1;
	if (val & BIT(IEEE80211_AC_VI))
	arg.trig_video = 1;
	if (val & BIT(IEEE80211_AC_BE))
	arg.trig_be = 1;
	if (val & BIT(IEEE80211_AC_BK))
	arg.trig_bckgrnd = 1;
	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_SET_UAPSD_INFORMATION,
	&arg, sizeof(arg));
	}

	static inline int hif_erp_use_protection(struct wfx_vif *wvif, bool enable)
	{
	struct hif_mib_non_erp_protection arg = {
	.use_cts_to_self = enable,
	};

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_NON_ERP_PROTECTION, &arg, sizeof(arg));
	}

	static inline int hif_slot_time(struct wfx_vif *wvif, int val)
	{
	struct hif_mib_slot_time arg = {
	.slot_time = cpu_to_le32(val),
	};

	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_SLOT_TIME,
	&arg, sizeof(arg));
	}

	static inline int hif_dual_cts_protection(struct wfx_vif *wvif, bool enable)
	{
	struct hif_mib_set_ht_protection arg = {
	.dual_cts_prot = enable,
	};

	return hif_write_mib(wvif->wdev, wvif->id, HIF_MIB_ID_SET_HT_PROTECTION,
	&arg, sizeof(arg));
	}

	static inline int hif_wep_default_key_id(struct wfx_vif *wvif, int val)
	{
	struct hif_mib_wep_default_key_id arg = {
	.wep_default_key_id = val,
	};

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_DOT11_WEP_DEFAULT_KEY_ID,
	&arg, sizeof(arg));
	}

	static inline int hif_rts_threshold(struct wfx_vif *wvif, int val)
	{
	struct hif_mib_dot11_rts_threshold arg = {
	.threshold = cpu_to_le32(val >= 0 ? val : 0xFFFF),
	};

	return hif_write_mib(wvif->wdev, wvif->id,
	HIF_MIB_ID_DOT11_RTS_THRESHOLD, &arg, sizeof(arg));
	}

	#endif