drivers/net/wireless/intel/iwlwifi/mei/iwl-mei.h - third_party/linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0-only
 /*
  * Copyright (C) 2021 Intel Corporation
  */

 #ifndef __iwl_mei_h__
 #define __iwl_mei_h__

 #include <linux/if_ether.h>
 #include <linux/skbuff.h>
 #include <linux/ieee80211.h>

 /**
  * DOC: Introduction
  *
  * iwlmei is the kernel module that is in charge of the commnunication between
  * the iwlwifi driver and the CSME firmware's WLAN driver. This communication
  * uses the SAP protocol defined in another file.
  * iwlwifi can request or release ownership on the WiFi device through iwlmei.
  * iwlmei may notify iwlwifi about certain events: what filter iwlwifi should
  * use to passthrough inbound packets to the CSME firmware for example. iwlmei
  * may also use iwlwifi to send traffic. This means that we need communication
  * from iwlmei to iwlwifi and the other way around.
  */

 /**
  * DOC: Life cycle
  *
  * iwlmei exports symbols that are needed by iwlwifi so that iwlmei will always
  * be loaded when iwlwifi is alive. iwlwifi registers itself to iwlmei and
  * provides the pointers to the functions that iwlmei calls whenever needed.
  * iwlwifi calls iwlmei through direct and context-free function calls.
  * It is assumed that only one device is accessible to the CSME firmware and
  * under the scope of iwlmei so that it is valid not to have any context passed
  * to iwlmei's functions.
  *
  * There are cases in which iwlmei can't access the CSME firmware, because the
  * CSME firmware is undergoing a reset, or the mei bus decided to unbind the
  * device. In those cases, iwlmei will need not to send requests over the mei
  * bus. Instead, it needs to cache the requests from iwlwifi and fulfill them
  * when the mei bus is available again.
  *
  * iwlmei can call iwlwifi as long as iwlwifi is registered to iwlmei. When
  * iwlwifi goes down (the PCI device is unbound, or the iwlwifi is unloaded)
  * iwlwifi needs to unregister from iwlmei.
  */

 /**
  * DOC: Memory layout
  *
  * Since iwlwifi calls iwlmei without any context, iwlmei needs to hold a
  * global pointer to its data (which is in the mei client device's private
  * data area). If there was no bind on the mei bus, this pointer is NULL and
  * iwlmei knows not access to the CSME firmware upon requests from iwlwifi.
  *
  * iwlmei needs to cache requests from iwlwifi when there is no mei client
  * device available (when iwlmei has been removed from the mei bus). In this
  * case, all iwlmei's data that resides in the mei client device's private data
  * area is unavailable. For this specific case, a separate caching area is
  * needed.
  */

 /**
  * DOC: Concurrency
  *
  * iwlwifi can call iwlmei at any time. iwlmei will take care to synchronize
  * the calls from iwlwifi with its internal flows. iwlwifi must not call iwlmei
  * in flows that cannot sleep. Moreover, iwlwifi must not call iwlmei in flows
  * that originated from iwlmei.
  */

 /**
  * DOC: Probe and remove from mei bus driver
  *
  * When the mei bus driver enumerates its devices, it calls the iwlmei's probe
  * function which will send the %SAP_ME_MSG_START message. The probe completes
  * before the response (%SAP_ME_MSG_START_OK) is received. This response will
  * be handle by the Rx path. Once it arrives, the connection to the CSME
  * firmware is considered established and iwlwifi's requests can be treated
  * against the CSME firmware.
  *
  * When the mei bus driver removes the device, iwlmei loses all the data that
  * was attached to the mei client device. It clears the global pointer to the
  * mei client device since it is not available anymore. This will cause all the
  * requests coming from iwlwifi to be cached. This flow takes the global mutex
  * to be synchronized with all the requests coming from iwlwifi.
  */

 /**
  * DOC: Driver load when CSME owns the device
  *
  * When the driver (iwlwifi) is loaded while CSME owns the device,
  * it'll ask CSME to release the device through HW registers. CSME
  * will release the device only in the case that there is no connection
  * through the mei bus. If there is a mei bus connection, CSME will refuse
  * to release the ownership on the device through the HW registers. In that
  * case, iwlwifi must first request ownership using the SAP protocol.
  *
  * Once iwlwifi will request ownership through the SAP protocol, CSME will
  * grant the ownership on the device through the HW registers as well.
  * In order to request ownership over SAP, we first need to have an interface
  * which means that we need to register to mac80211.
  * This can't happen before we get the NVM that contains all the capabilities
  * of the device. Reading the NVM usually requires the load the firmware, but
  * this is impossible as long as we don't have ownership on the device.
  * In order to solve this chicken and egg problem, the host driver can get
  * the NVM through CSME which owns the device. It can send
  * %SAP_MSG_NOTIF_GET_NVM, which will be replied by %SAP_MSG_NOTIF_NVM with
  * the NVM's content that the host driver needs.
  */

 /**
  * DOC: CSME behavior regarding the ownership requests
  *
  * The ownership requests from the host can come in two different ways:
  *  - the HW registers in iwl_pcie_set_hw_ready
  *  - using the Software Arbitration Protocol (SAP)
  *
  * The host can ask CSME who owns the device with %SAP_MSG_NOTIF_WHO_OWNS_NIC,
  * and it can request ownership with %SAP_MSG_NOTIF_HOST_ASKS_FOR_NIC_OWNERSHIP.
  * The host will first use %SAP_MSG_NOTIF_WHO_OWNS_NIC to know what state
  * CSME is in. In case CSME thinks it owns the device, the host can ask for
  * ownership with %SAP_MSG_NOTIF_HOST_ASKS_FOR_NIC_OWNERSHIP.
  *
  * Here the table that describes CSME's behavior upon ownership request:
  *
  * +-------------------+------------+--------------+-----------------------------+------------+
  * | State             | HW reg bit | Reply for    | Event                       | HW reg bit |
  * |                   | before     | WHO_OWNS_NIC |                             | after      |
  * +===================+============+==============+=============================+============+
  * | WiAMT not         | 0          | Host         | HW register or              | 0          |
  * | operational       | Host owner |              | HOST_ASKS_FOR_NIC_OWNERSHIP | Host owner |
  * +-------------------+------------+--------------+-----------------------------+------------+
  * | Operational &     | 1          | N/A          | HW register                 | 0          |
  * | SAP down &        | CSME owner |              |                             | Host owner |
  * | no session active |            |              |                             |            |
  * +-------------------+------------+--------------+-----------------------------+------------+
  * | Operational &     | 1          | CSME         | HW register                 | 1          |
  * | SAP up            | CSME owner |              |                             | CSME owner |
  * +-------------------+------------+--------------+-----------------------------+------------+
  * | Operational &     | 1          | CSME         | HOST_ASKS_FOR_NIC_OWNERSHIP | 0          |
  * | SAP up            | CSME owner |              |                             | Host owner |
  * +-------------------+------------+--------------+-----------------------------+------------+
  */

 /**
  * DOC: Driver load when CSME is associated and a session is active
  *
  * A "session" is active when CSME is associated to an access point and the
  * link is used to attach a remote driver or to control the system remotely.
  * When a session is active, we want to make sure it won't disconnect when we
  * take ownership on the device.
  * In this case, the driver can get the device, but it'll need to make
  * sure that it'll connect to the exact same AP (same BSSID).
  * In order to do so, CSME will send the connection parameters through
  * SAP and then the host can check if it can connect to this same AP.
  * If yes, it can request ownership through SAP and connect quickly without
  * scanning all the channels, but just probing the AP on the channel that
  * CSME was connected to.
  * In order to signal this specific scenario to iwlwifi, iwlmei will
  * immediately require iwlwifi to report RF-Kill to the network stack. This
  * RF-Kill will prevent the stack from getting the device, and it has a reason
  * that tells the userspace that the device is in RF-Kill because it is not
  * owned by the host. Once the userspace has configured the right profile,
  * it'll be able to let iwlmei know that it can request ownership over SAP
  * which will remove the RF-Kill, and finally allow the host to connect.
  * The host has then 3 seconds to connect (including DHCP). Had the host
  * failed to connect within those 3 seconds, CSME will take the device back.
  */

 /**
  * DOC: Datapath
  *
  * CSME can transmit packets, through the netdev that it gets from the wifi
  * driver. It'll send packet in the 802.3 format and simply call
  * dev_queue_xmit.
  *
  * For Rx, iwlmei registers a Rx handler that it attaches to the netdev. iwlmei
  * may catch packets and send them to CSME, it can then either drop them so
  * that they are invisible to user space, or let them go the user space.
  *
  * Packets transmitted by the user space do not need to be forwarded to CSME
  * with the exception of the DHCP request. In order to know what IP is used
  * by the user space, CSME needs to get the DHCP request. See
  * iwl_mei_tx_copy_to_csme().
  */

 /**
  * enum iwl_mei_nvm_caps - capabilities for MEI NVM
  * @MEI_NVM_CAPS_LARI_SUPPORT: Lari is supported
  * @MEI_NVM_CAPS_11AX_SUPPORT: 11AX is supported
  */
 enum iwl_mei_nvm_caps {
 	MEI_NVM_CAPS_LARI_SUPPORT	= BIT(0),
 	MEI_NVM_CAPS_11AX_SUPPORT	= BIT(1),
 };

 /**
  * struct iwl_mei_nvm - used to pass the NVM from CSME
  * @hw_addr: The MAC address
  * @n_hw_addrs: The number of MAC addresses
  * @reserved: For alignment.
  * @radio_cfg: The radio configuration.
  * @caps: See &enum iwl_mei_nvm_caps.
  * @nvm_version: The version of the NVM.
  * @channels: The data for each channel.
  *
  * If a field is added, it must correspond to the SAP structure.
  */
 struct iwl_mei_nvm {
 	u8 hw_addr[ETH_ALEN];
 	u8 n_hw_addrs;
 	u8 reserved;
 	u32 radio_cfg;
 	u32 caps;
 	u32 nvm_version;
 	u32 channels[110];
 };

 /**
  * enum iwl_mei_pairwise_cipher - cipher for UCAST key
  * @IWL_MEI_CIPHER_NONE: none
  * @IWL_MEI_CIPHER_CCMP: ccmp
  * @IWL_MEI_CIPHER_GCMP: gcmp
  * @IWL_MEI_CIPHER_GCMP_256: gcmp 256
  *
  * Note that those values are dictated by the CSME firmware API (see sap.h)
  */
 enum iwl_mei_pairwise_cipher {
 	IWL_MEI_CIPHER_NONE	= 0,
 	IWL_MEI_CIPHER_CCMP	= 4,
 	IWL_MEI_CIPHER_GCMP	= 8,
 	IWL_MEI_CIPHER_GCMP_256 = 9,
 };

 /**
  * enum iwl_mei_akm_auth - a combination of AKM and AUTH method
  * @IWL_MEI_AKM_AUTH_OPEN: No encryption
  * @IWL_MEI_AKM_AUTH_RSNA: 1X profile
  * @IWL_MEI_AKM_AUTH_RSNA_PSK: PSK profile
  * @IWL_MEI_AKM_AUTH_SAE: SAE profile
  *
  * Note that those values are dictated by the CSME firmware API (see sap.h)
  */
 enum iwl_mei_akm_auth {
 	IWL_MEI_AKM_AUTH_OPEN		= 0,
 	IWL_MEI_AKM_AUTH_RSNA		= 6,
 	IWL_MEI_AKM_AUTH_RSNA_PSK	= 7,
 	IWL_MEI_AKM_AUTH_SAE		= 9,
 };

 /**
  * struct iwl_mei_conn_info - connection info
  * @lp_state: link protection state
  * @auth_mode: authentication mode
  * @ssid_len: the length of SSID
  * @ssid: the SSID
  * @pairwise_cipher: the cipher used for unicast packets
  * @channel: the associated channel
  * @band: the associated band
  * @bssid: the BSSID
  */
 struct iwl_mei_conn_info {
 	u8 lp_state;
 	u8 auth_mode;
 	u8 ssid_len;
 	u8 channel;
 	u8 band;
 	u8 pairwise_cipher;
 	u8 bssid[ETH_ALEN];
 	u8 ssid[IEEE80211_MAX_SSID_LEN];
 };

 /**
  * struct iwl_mei_colloc_info - collocated AP info
  * @channel: the channel of the collocated AP
  * @bssid: the BSSID of the collocated AP
  */
 struct iwl_mei_colloc_info {
 	u8 channel;
 	u8 bssid[ETH_ALEN];
 };

 /*
  * struct iwl_mei_ops - driver's operations called by iwlmei
  * Operations will not be called more than once concurrently.
  * It's not allowed to call iwlmei functions from this context.
  *
  * @me_conn_status: provide information about CSME's current connection.
  * @rfkill: called when the wifi driver should report a change in the rfkill
  *	status.
  * @roaming_forbidden: indicates whether roaming is forbidden.
  * @sap_connected: indicate that SAP is now connected. Will be called in case
  *	the wifi driver registered to iwlmei before SAP connection succeeded or
  *	when the SAP connection is re-established.
  * @nic_stolen: this means that device is no longer available. The device can
  *	still be used until the callback returns.
  */
 struct iwl_mei_ops {
 	void (*me_conn_status)(void *priv,
 			       const struct iwl_mei_conn_info *conn_info);
 	void (*rfkill)(void *priv, bool blocked);
 	void (*roaming_forbidden)(void *priv, bool forbidden);
 	void (*sap_connected)(void *priv);
 	void (*nic_stolen)(void *priv);
 };

 #if IS_ENABLED(CONFIG_IWLMEI)

 /**
  * iwl_mei_is_connected() - is the connection to the CSME firmware established?
  *
  * Return: true if we have a SAP connection
  */
 bool iwl_mei_is_connected(void);

 /**
  * iwl_mei_get_nvm() - returns the NVM for the device
  *
  * It is the caller's responsibility to free the memory returned
  * by this function.
  * This function blocks (sleeps) until the NVM is ready.
  *
  * Return: the NVM as received from CSME
  */
 struct iwl_mei_nvm *iwl_mei_get_nvm(void);

 /**
  * iwl_mei_get_ownership() - request ownership
  *
  * This function blocks until ownership is granted or timeout expired.
  *
  * Return: 0 in case we could get ownership on the device
  */
 int iwl_mei_get_ownership(void);

 /**
  * iwl_mei_set_rfkill_state() - set SW and HW RF kill states
  * @hw_rfkill: HW RF kill state.
  * @sw_rfkill: SW RF kill state.
  *
  * This function must be called when SW RF kill is issued by the user.
  */
 void iwl_mei_set_rfkill_state(bool hw_rfkill, bool sw_rfkill);

 /**
  * iwl_mei_set_nic_info() - set mac address
  * @mac_address: mac address to set
  * @nvm_address: NVM mac adsress to set
  *
  * This function must be called upon mac address change.
  */
 void iwl_mei_set_nic_info(const u8 *mac_address, const u8 *nvm_address);

 /**
  * iwl_mei_set_country_code() - set new country code
  * @mcc: the new applied MCC
  *
  * This function must be called upon country code update
  */
 void iwl_mei_set_country_code(u16 mcc);

 /**
  * iwl_mei_set_power_limit() - set TX power limit
  * @power_limit: pointer to an array of 10 elements (le16) represents the power
  * restrictions per chain.
  *
  * This function must be called upon power restrictions change
  */
 void iwl_mei_set_power_limit(const __le16 *power_limit);

 /**
  * iwl_mei_register() - register the wifi driver to iwlmei
  * @priv: a pointer to the wifi driver's context. Cannot be NULL.
  * @ops: the ops structure.
  *
  * Return: 0 unless something went wrong. It is illegal to call any
  * other API function before this function is called and succeeds.
  *
  * Only one wifi driver instance (wifi device instance really)
  * can register at a time.
  */
 int iwl_mei_register(void *priv, const struct iwl_mei_ops *ops);

 /**
  * iwl_mei_start_unregister() - unregister the wifi driver from iwlmei
  *
  * From this point on, iwlmei will not used the callbacks provided by
  * the driver, but the device is still usable.
  */
 void iwl_mei_start_unregister(void);

 /**
  * iwl_mei_unregister_complete() - complete the unregistration
  *
  * Must be called after iwl_mei_start_unregister. When this function returns,
  * the device is owned by CSME.
  */
 void iwl_mei_unregister_complete(void);

 /**
  * iwl_mei_set_netdev() - sets the netdev for Tx / Rx.
  * @netdev: the net_device
  *
  * The caller should set the netdev to a non-NULL value when the
  * interface is added. Packets might be sent to the driver immediately
  * afterwards.
  * The caller should set the netdev to NULL when the interface is removed.
  * This function will call synchronize_net() after setting the netdev to NULL.
  * Only when this function returns, can the caller assume that iwlmei will
  * no longer inject packets into the netdev's Tx path.
  *
  * Context: This function can sleep and assumes rtnl_lock is taken.
  * The netdev must be set to NULL before iwl_mei_start_unregister() is called.
  */
 void iwl_mei_set_netdev(struct net_device *netdev);

 /**
  * iwl_mei_tx_copy_to_csme() - must be called for each packet sent by
  * the wifi driver.
  * @skb: the skb sent
  * @ivlen: the size of the IV that needs to be skipped after the MAC and
  *	before the SNAP header.
  *
  * This function doesn't take any lock, it simply tries to catch DHCP
  * packets sent by the wifi driver. If the packet is a DHCP packet, it
  * will send it to CSME. This function must not be called for virtual
  * interfaces that are not monitored by CSME, meaning it must be called
  * only for packets transmitted by the netdevice that was registered
  * with iwl_mei_set_netdev().
  */
 void iwl_mei_tx_copy_to_csme(struct sk_buff *skb, unsigned int ivlen);

 /**
  * iwl_mei_host_associated() - must be called when iwlwifi associated.
  * @conn_info: pointer to the connection info structure.
  * @colloc_info: pointer to the collocated AP info. This is relevant only in
  *	case of UHB associated AP, otherwise set to NULL.
  */
 void iwl_mei_host_associated(const struct iwl_mei_conn_info *conn_info,
 			     const struct iwl_mei_colloc_info *colloc_info);

 /**
  * iwl_mei_host_disassociated() - must be called when iwlwifi disassociated.
  */
 void iwl_mei_host_disassociated(void);

 /**
  * iwl_mei_device_down() - must be called when the device is down
  */
 void iwl_mei_device_down(void);

 #else

 static inline bool iwl_mei_is_connected(void)
 { return false; }

 static inline struct iwl_mei_nvm *iwl_mei_get_nvm(void)
 { return NULL; }

 static inline int iwl_mei_get_ownership(void)
 { return 0; }

 static inline void iwl_mei_set_rfkill_state(bool hw_rfkill, bool sw_rfkill)
 {}

 static inline void iwl_mei_set_nic_info(const u8 *mac_address, const u8 *nvm_address)
 {}

 static inline void iwl_mei_set_country_code(u16 mcc)
 {}

 static inline void iwl_mei_set_power_limit(__le16 *power_limit)
 {}

 static inline int iwl_mei_register(void *priv,
 				   const struct iwl_mei_ops *ops)
 { return 0; }

 static inline void iwl_mei_start_unregister(void)
 {}

 static inline void iwl_mei_unregister_complete(void)
 {}

 static inline void iwl_mei_set_netdev(struct net_device *netdev)
 {}

 static inline void iwl_mei_tx_copy_to_csme(struct sk_buff *skb,
 					   unsigned int ivlen)
 {}

 static inline void iwl_mei_host_associated(const struct iwl_mei_conn_info *conn_info,
 					   const struct iwl_mei_colloc_info *colloc_info)
 {}

 static inline void iwl_mei_host_disassociated(void)
 {}

 static inline void iwl_mei_device_down(void)
 {}

 #endif /* CONFIG_IWLMEI */

 #endif /* __iwl_mei_h__ */
	// SPDX-License-Identifier: GPL-2.0-only
	/*
	* Copyright (C) 2021 Intel Corporation
	*/

	#ifndef __iwl_mei_h__
	#define __iwl_mei_h__

	#include <linux/if_ether.h>
	#include <linux/skbuff.h>
	#include <linux/ieee80211.h>

	/**
	* DOC: Introduction
	*
	* iwlmei is the kernel module that is in charge of the commnunication between
	* the iwlwifi driver and the CSME firmware's WLAN driver. This communication
	* uses the SAP protocol defined in another file.
	* iwlwifi can request or release ownership on the WiFi device through iwlmei.
	* iwlmei may notify iwlwifi about certain events: what filter iwlwifi should
	* use to passthrough inbound packets to the CSME firmware for example. iwlmei
	* may also use iwlwifi to send traffic. This means that we need communication
	* from iwlmei to iwlwifi and the other way around.
	*/

	/**
	* DOC: Life cycle
	*
	* iwlmei exports symbols that are needed by iwlwifi so that iwlmei will always
	* be loaded when iwlwifi is alive. iwlwifi registers itself to iwlmei and
	* provides the pointers to the functions that iwlmei calls whenever needed.
	* iwlwifi calls iwlmei through direct and context-free function calls.
	* It is assumed that only one device is accessible to the CSME firmware and
	* under the scope of iwlmei so that it is valid not to have any context passed
	* to iwlmei's functions.
	*
	* There are cases in which iwlmei can't access the CSME firmware, because the
	* CSME firmware is undergoing a reset, or the mei bus decided to unbind the
	* device. In those cases, iwlmei will need not to send requests over the mei
	* bus. Instead, it needs to cache the requests from iwlwifi and fulfill them
	* when the mei bus is available again.
	*
	* iwlmei can call iwlwifi as long as iwlwifi is registered to iwlmei. When
	* iwlwifi goes down (the PCI device is unbound, or the iwlwifi is unloaded)
	* iwlwifi needs to unregister from iwlmei.
	*/

	/**
	* DOC: Memory layout
	*
	* Since iwlwifi calls iwlmei without any context, iwlmei needs to hold a
	* global pointer to its data (which is in the mei client device's private
	* data area). If there was no bind on the mei bus, this pointer is NULL and
	* iwlmei knows not access to the CSME firmware upon requests from iwlwifi.
	*
	* iwlmei needs to cache requests from iwlwifi when there is no mei client
	* device available (when iwlmei has been removed from the mei bus). In this
	* case, all iwlmei's data that resides in the mei client device's private data
	* area is unavailable. For this specific case, a separate caching area is
	* needed.
	*/

	/**
	* DOC: Concurrency
	*
	* iwlwifi can call iwlmei at any time. iwlmei will take care to synchronize
	* the calls from iwlwifi with its internal flows. iwlwifi must not call iwlmei
	* in flows that cannot sleep. Moreover, iwlwifi must not call iwlmei in flows
	* that originated from iwlmei.
	*/

	/**
	* DOC: Probe and remove from mei bus driver
	*
	* When the mei bus driver enumerates its devices, it calls the iwlmei's probe
	* function which will send the %SAP_ME_MSG_START message. The probe completes
	* before the response (%SAP_ME_MSG_START_OK) is received. This response will
	* be handle by the Rx path. Once it arrives, the connection to the CSME
	* firmware is considered established and iwlwifi's requests can be treated
	* against the CSME firmware.
	*
	* When the mei bus driver removes the device, iwlmei loses all the data that
	* was attached to the mei client device. It clears the global pointer to the
	* mei client device since it is not available anymore. This will cause all the
	* requests coming from iwlwifi to be cached. This flow takes the global mutex
	* to be synchronized with all the requests coming from iwlwifi.
	*/

	/**
	* DOC: Driver load when CSME owns the device
	*
	* When the driver (iwlwifi) is loaded while CSME owns the device,
	* it'll ask CSME to release the device through HW registers. CSME
	* will release the device only in the case that there is no connection
	* through the mei bus. If there is a mei bus connection, CSME will refuse
	* to release the ownership on the device through the HW registers. In that
	* case, iwlwifi must first request ownership using the SAP protocol.
	*
	* Once iwlwifi will request ownership through the SAP protocol, CSME will
	* grant the ownership on the device through the HW registers as well.
	* In order to request ownership over SAP, we first need to have an interface
	* which means that we need to register to mac80211.
	* This can't happen before we get the NVM that contains all the capabilities
	* of the device. Reading the NVM usually requires the load the firmware, but
	* this is impossible as long as we don't have ownership on the device.
	* In order to solve this chicken and egg problem, the host driver can get
	* the NVM through CSME which owns the device. It can send
	* %SAP_MSG_NOTIF_GET_NVM, which will be replied by %SAP_MSG_NOTIF_NVM with
	* the NVM's content that the host driver needs.
	*/

	/**
	* DOC: CSME behavior regarding the ownership requests
	*
	* The ownership requests from the host can come in two different ways:
	* - the HW registers in iwl_pcie_set_hw_ready
	* - using the Software Arbitration Protocol (SAP)
	*
	* The host can ask CSME who owns the device with %SAP_MSG_NOTIF_WHO_OWNS_NIC,
	* and it can request ownership with %SAP_MSG_NOTIF_HOST_ASKS_FOR_NIC_OWNERSHIP.
	* The host will first use %SAP_MSG_NOTIF_WHO_OWNS_NIC to know what state
	* CSME is in. In case CSME thinks it owns the device, the host can ask for
	* ownership with %SAP_MSG_NOTIF_HOST_ASKS_FOR_NIC_OWNERSHIP.
	*
	* Here the table that describes CSME's behavior upon ownership request:
	*
	* +-------------------+------------+--------------+-----------------------------+------------+
	* \| State \| HW reg bit \| Reply for \| Event \| HW reg bit \|
	* \| \| before \| WHO_OWNS_NIC \| \| after \|
	* +===================+============+==============+=============================+============+
	* \| WiAMT not \| 0 \| Host \| HW register or \| 0 \|
	* \| operational \| Host owner \| \| HOST_ASKS_FOR_NIC_OWNERSHIP \| Host owner \|
	* +-------------------+------------+--------------+-----------------------------+------------+
	* \| Operational & \| 1 \| N/A \| HW register \| 0 \|
	* \| SAP down & \| CSME owner \| \| \| Host owner \|
	* \| no session active \| \| \| \| \|
	* +-------------------+------------+--------------+-----------------------------+------------+
	* \| Operational & \| 1 \| CSME \| HW register \| 1 \|
	* \| SAP up \| CSME owner \| \| \| CSME owner \|
	* +-------------------+------------+--------------+-----------------------------+------------+
	* \| Operational & \| 1 \| CSME \| HOST_ASKS_FOR_NIC_OWNERSHIP \| 0 \|
	* \| SAP up \| CSME owner \| \| \| Host owner \|
	* +-------------------+------------+--------------+-----------------------------+------------+
	*/

	/**
	* DOC: Driver load when CSME is associated and a session is active
	*
	* A "session" is active when CSME is associated to an access point and the
	* link is used to attach a remote driver or to control the system remotely.
	* When a session is active, we want to make sure it won't disconnect when we
	* take ownership on the device.
	* In this case, the driver can get the device, but it'll need to make
	* sure that it'll connect to the exact same AP (same BSSID).
	* In order to do so, CSME will send the connection parameters through
	* SAP and then the host can check if it can connect to this same AP.
	* If yes, it can request ownership through SAP and connect quickly without
	* scanning all the channels, but just probing the AP on the channel that
	* CSME was connected to.
	* In order to signal this specific scenario to iwlwifi, iwlmei will
	* immediately require iwlwifi to report RF-Kill to the network stack. This
	* RF-Kill will prevent the stack from getting the device, and it has a reason
	* that tells the userspace that the device is in RF-Kill because it is not
	* owned by the host. Once the userspace has configured the right profile,
	* it'll be able to let iwlmei know that it can request ownership over SAP
	* which will remove the RF-Kill, and finally allow the host to connect.
	* The host has then 3 seconds to connect (including DHCP). Had the host
	* failed to connect within those 3 seconds, CSME will take the device back.
	*/

	/**
	* DOC: Datapath
	*
	* CSME can transmit packets, through the netdev that it gets from the wifi
	* driver. It'll send packet in the 802.3 format and simply call
	* dev_queue_xmit.
	*
	* For Rx, iwlmei registers a Rx handler that it attaches to the netdev. iwlmei
	* may catch packets and send them to CSME, it can then either drop them so
	* that they are invisible to user space, or let them go the user space.
	*
	* Packets transmitted by the user space do not need to be forwarded to CSME
	* with the exception of the DHCP request. In order to know what IP is used
	* by the user space, CSME needs to get the DHCP request. See
	* iwl_mei_tx_copy_to_csme().
	*/

	/**
	* enum iwl_mei_nvm_caps - capabilities for MEI NVM
	* @MEI_NVM_CAPS_LARI_SUPPORT: Lari is supported
	* @MEI_NVM_CAPS_11AX_SUPPORT: 11AX is supported
	*/
	enum iwl_mei_nvm_caps {
	MEI_NVM_CAPS_LARI_SUPPORT = BIT(0),
	MEI_NVM_CAPS_11AX_SUPPORT = BIT(1),
	};

	/**
	* struct iwl_mei_nvm - used to pass the NVM from CSME
	* @hw_addr: The MAC address
	* @n_hw_addrs: The number of MAC addresses
	* @reserved: For alignment.
	* @radio_cfg: The radio configuration.
	* @caps: See &enum iwl_mei_nvm_caps.
	* @nvm_version: The version of the NVM.
	* @channels: The data for each channel.
	*
	* If a field is added, it must correspond to the SAP structure.
	*/
	struct iwl_mei_nvm {
	u8 hw_addr[ETH_ALEN];
	u8 n_hw_addrs;
	u8 reserved;
	u32 radio_cfg;
	u32 caps;
	u32 nvm_version;
	u32 channels[110];
	};

	/**
	* enum iwl_mei_pairwise_cipher - cipher for UCAST key
	* @IWL_MEI_CIPHER_NONE: none
	* @IWL_MEI_CIPHER_CCMP: ccmp
	* @IWL_MEI_CIPHER_GCMP: gcmp
	* @IWL_MEI_CIPHER_GCMP_256: gcmp 256
	*
	* Note that those values are dictated by the CSME firmware API (see sap.h)
	*/
	enum iwl_mei_pairwise_cipher {
	IWL_MEI_CIPHER_NONE = 0,
	IWL_MEI_CIPHER_CCMP = 4,
	IWL_MEI_CIPHER_GCMP = 8,
	IWL_MEI_CIPHER_GCMP_256 = 9,
	};

	/**
	* enum iwl_mei_akm_auth - a combination of AKM and AUTH method
	* @IWL_MEI_AKM_AUTH_OPEN: No encryption
	* @IWL_MEI_AKM_AUTH_RSNA: 1X profile
	* @IWL_MEI_AKM_AUTH_RSNA_PSK: PSK profile
	* @IWL_MEI_AKM_AUTH_SAE: SAE profile
	*
	* Note that those values are dictated by the CSME firmware API (see sap.h)
	*/
	enum iwl_mei_akm_auth {
	IWL_MEI_AKM_AUTH_OPEN = 0,
	IWL_MEI_AKM_AUTH_RSNA = 6,
	IWL_MEI_AKM_AUTH_RSNA_PSK = 7,
	IWL_MEI_AKM_AUTH_SAE = 9,
	};

	/**
	* struct iwl_mei_conn_info - connection info
	* @lp_state: link protection state
	* @auth_mode: authentication mode
	* @ssid_len: the length of SSID
	* @ssid: the SSID
	* @pairwise_cipher: the cipher used for unicast packets
	* @channel: the associated channel
	* @band: the associated band
	* @bssid: the BSSID
	*/
	struct iwl_mei_conn_info {
	u8 lp_state;
	u8 auth_mode;
	u8 ssid_len;
	u8 channel;
	u8 band;
	u8 pairwise_cipher;
	u8 bssid[ETH_ALEN];
	u8 ssid[IEEE80211_MAX_SSID_LEN];
	};

	/**
	* struct iwl_mei_colloc_info - collocated AP info
	* @channel: the channel of the collocated AP
	* @bssid: the BSSID of the collocated AP
	*/
	struct iwl_mei_colloc_info {
	u8 channel;
	u8 bssid[ETH_ALEN];
	};

	/*
	* struct iwl_mei_ops - driver's operations called by iwlmei
	* Operations will not be called more than once concurrently.
	* It's not allowed to call iwlmei functions from this context.
	*
	* @me_conn_status: provide information about CSME's current connection.
	* @rfkill: called when the wifi driver should report a change in the rfkill
	* status.
	* @roaming_forbidden: indicates whether roaming is forbidden.
	* @sap_connected: indicate that SAP is now connected. Will be called in case
	* the wifi driver registered to iwlmei before SAP connection succeeded or
	* when the SAP connection is re-established.
	* @nic_stolen: this means that device is no longer available. The device can
	* still be used until the callback returns.
	*/
	struct iwl_mei_ops {
	void (me_conn_status)(void priv,
	const struct iwl_mei_conn_info *conn_info);
	void (rfkill)(void priv, bool blocked);
	void (roaming_forbidden)(void priv, bool forbidden);
	void (sap_connected)(void priv);
	void (nic_stolen)(void priv);
	};

	#if IS_ENABLED(CONFIG_IWLMEI)

	/**
	* iwl_mei_is_connected() - is the connection to the CSME firmware established?
	*
	* Return: true if we have a SAP connection
	*/
	bool iwl_mei_is_connected(void);

	/**
	* iwl_mei_get_nvm() - returns the NVM for the device
	*
	* It is the caller's responsibility to free the memory returned
	* by this function.
	* This function blocks (sleeps) until the NVM is ready.
	*
	* Return: the NVM as received from CSME
	*/
	struct iwl_mei_nvm *iwl_mei_get_nvm(void);

	/**
	* iwl_mei_get_ownership() - request ownership
	*
	* This function blocks until ownership is granted or timeout expired.
	*
	* Return: 0 in case we could get ownership on the device
	*/
	int iwl_mei_get_ownership(void);

	/**
	* iwl_mei_set_rfkill_state() - set SW and HW RF kill states
	* @hw_rfkill: HW RF kill state.
	* @sw_rfkill: SW RF kill state.
	*
	* This function must be called when SW RF kill is issued by the user.
	*/
	void iwl_mei_set_rfkill_state(bool hw_rfkill, bool sw_rfkill);

	/**
	* iwl_mei_set_nic_info() - set mac address
	* @mac_address: mac address to set
	* @nvm_address: NVM mac adsress to set
	*
	* This function must be called upon mac address change.
	*/
	void iwl_mei_set_nic_info(const u8 mac_address, const u8 nvm_address);

	/**
	* iwl_mei_set_country_code() - set new country code
	* @mcc: the new applied MCC
	*
	* This function must be called upon country code update
	*/
	void iwl_mei_set_country_code(u16 mcc);

	/**
	* iwl_mei_set_power_limit() - set TX power limit
	* @power_limit: pointer to an array of 10 elements (le16) represents the power
	* restrictions per chain.
	*
	* This function must be called upon power restrictions change
	*/
	void iwl_mei_set_power_limit(const __le16 *power_limit);

	/**
	* iwl_mei_register() - register the wifi driver to iwlmei
	* @priv: a pointer to the wifi driver's context. Cannot be NULL.
	* @ops: the ops structure.
	*
	* Return: 0 unless something went wrong. It is illegal to call any
	* other API function before this function is called and succeeds.
	*
	* Only one wifi driver instance (wifi device instance really)
	* can register at a time.
	*/
	int iwl_mei_register(void priv, const struct iwl_mei_ops ops);

	/**
	* iwl_mei_start_unregister() - unregister the wifi driver from iwlmei
	*
	* From this point on, iwlmei will not used the callbacks provided by
	* the driver, but the device is still usable.
	*/
	void iwl_mei_start_unregister(void);

	/**
	* iwl_mei_unregister_complete() - complete the unregistration
	*
	* Must be called after iwl_mei_start_unregister. When this function returns,
	* the device is owned by CSME.
	*/
	void iwl_mei_unregister_complete(void);

	/**
	* iwl_mei_set_netdev() - sets the netdev for Tx / Rx.
	* @netdev: the net_device
	*
	* The caller should set the netdev to a non-NULL value when the
	* interface is added. Packets might be sent to the driver immediately
	* afterwards.
	* The caller should set the netdev to NULL when the interface is removed.
	* This function will call synchronize_net() after setting the netdev to NULL.
	* Only when this function returns, can the caller assume that iwlmei will
	* no longer inject packets into the netdev's Tx path.
	*
	* Context: This function can sleep and assumes rtnl_lock is taken.
	* The netdev must be set to NULL before iwl_mei_start_unregister() is called.
	*/
	void iwl_mei_set_netdev(struct net_device *netdev);

	/**
	* iwl_mei_tx_copy_to_csme() - must be called for each packet sent by
	* the wifi driver.
	* @skb: the skb sent
	* @ivlen: the size of the IV that needs to be skipped after the MAC and
	* before the SNAP header.
	*
	* This function doesn't take any lock, it simply tries to catch DHCP
	* packets sent by the wifi driver. If the packet is a DHCP packet, it
	* will send it to CSME. This function must not be called for virtual
	* interfaces that are not monitored by CSME, meaning it must be called
	* only for packets transmitted by the netdevice that was registered
	* with iwl_mei_set_netdev().
	*/
	void iwl_mei_tx_copy_to_csme(struct sk_buff *skb, unsigned int ivlen);

	/**
	* iwl_mei_host_associated() - must be called when iwlwifi associated.
	* @conn_info: pointer to the connection info structure.
	* @colloc_info: pointer to the collocated AP info. This is relevant only in
	* case of UHB associated AP, otherwise set to NULL.
	*/
	void iwl_mei_host_associated(const struct iwl_mei_conn_info *conn_info,
	const struct iwl_mei_colloc_info *colloc_info);

	/**
	* iwl_mei_host_disassociated() - must be called when iwlwifi disassociated.
	*/
	void iwl_mei_host_disassociated(void);

	/**
	* iwl_mei_device_down() - must be called when the device is down
	*/
	void iwl_mei_device_down(void);

	#else

	static inline bool iwl_mei_is_connected(void)
	{ return false; }

	static inline struct iwl_mei_nvm *iwl_mei_get_nvm(void)
	{ return NULL; }

	static inline int iwl_mei_get_ownership(void)
	{ return 0; }

	static inline void iwl_mei_set_rfkill_state(bool hw_rfkill, bool sw_rfkill)
	{}

	static inline void iwl_mei_set_nic_info(const u8 mac_address, const u8 nvm_address)
	{}

	static inline void iwl_mei_set_country_code(u16 mcc)
	{}

	static inline void iwl_mei_set_power_limit(__le16 *power_limit)
	{}

	static inline int iwl_mei_register(void *priv,
	const struct iwl_mei_ops *ops)
	{ return 0; }

	static inline void iwl_mei_start_unregister(void)
	{}

	static inline void iwl_mei_unregister_complete(void)
	{}

	static inline void iwl_mei_set_netdev(struct net_device *netdev)
	{}

	static inline void iwl_mei_tx_copy_to_csme(struct sk_buff *skb,
	unsigned int ivlen)
	{}

	static inline void iwl_mei_host_associated(const struct iwl_mei_conn_info *conn_info,
	const struct iwl_mei_colloc_info *colloc_info)
	{}

	static inline void iwl_mei_host_disassociated(void)
	{}

	static inline void iwl_mei_device_down(void)
	{}

	#endif /* CONFIG_IWLMEI */

	#endif /* __iwl_mei_h__ */