wifi/1.6/IWifiChip.hal - LeafOS-Project/android_hardware_interfaces - Gitiles

 /*
  * Copyright 2022 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 package android.hardware.wifi@1.6;

 import @1.0::ChipModeId;
 import @1.0::IWifiIface;
 import @1.0::WifiStatus;
 import @1.5::WifiBand;
 import @1.5::IWifiChip;
 import @1.5::WifiIfaceMode;
 import IWifiRttController;

 /**
  * Interface that represents a chip that must be configured as a single unit.
  */
 interface IWifiChip extends @1.5::IWifiChip {
     /**
      * Usable Wifi channels filter masks.
      */
     enum UsableChannelFilter : @1.5::IWifiChip.UsableChannelFilter {
         /**
          * Filter Wifi channels that are supported for NAN3.1 Instant communication mode. This
          * filter should only be applied to NAN interface.
          * - If 5G is supported default discovery channel 149/44 is considered,
          * - If 5G is not supported then channel 6 has to be considered.
          */
         NAN_INSTANT_MODE = 1 << 2,
     };

     /**
      * Create a RTTController instance.
      *
      * RTT controller can be either:
      * a) Bound to a specific iface by passing in the corresponding |IWifiIface|
      * object in |iface| param, OR
      * b) Let the implementation decide the iface to use for RTT operations by
      * passing null in |iface| param.
      *
      * @param boundIface HIDL interface object representing the iface if
      *        the responder must be bound to a specific iface, null otherwise.
      * @return status WifiStatus of the operation.
      *         Possible status codes:
      *         |WifiStatusCode.SUCCESS|,
      *         |WifiStatusCode.ERROR_WIFI_CHIP_INVALID|
      */
     createRttController_1_6(IWifiIface boundIface)
         generates (WifiStatus status, IWifiRttController rtt);

     /**
      * Retrieve list of usable Wifi channels for the specified band &
      * operational modes.
      *
      * The list of usable Wifi channels in a given band depends on factors
      * like current country code, operational mode (e.g. STA, SAP, WFD-CLI,
      * WFD-GO, TDLS, NAN) and other restrictons due to DFS, cellular coexistence
      * and conncurency state of the device.
      *
      * @param band |WifiBand| for which list of usable channels is requested.
      * @param ifaceModeMask Bitmask of the modes represented by |WifiIfaceMode|
      *        Bitmask respresents all the modes that the caller is interested
      *        in (e.g. STA, SAP, CLI, GO, TDLS, NAN). E.g. If the caller is
      *        interested in knowing usable channels for P2P CLI, P2P GO & NAN,
      *        ifaceModeMask would be set to
      *        IFACE_MODE_P2P_CLIENT|IFACE_MODE_P2P_GO|IFACE_MODE_NAN.
      * @param filterMask Bitmask of filters represented by
      *        |UsableChannelFilter|. Specifies whether driver should filter
      *        channels based on additional criteria. If no filter is specified
      *        driver should return usable channels purely based on regulatory
      *        constraints.
      * @return status WifiStatus of the operation.
      *         Possible status codes:
      *         |WifiStatusCode.SUCCESS|,
      *         |WifiStatusCode.ERROR_NOT_SUPPORTED|,
      *         |WifiStatusCode.ERROR_INVALID_ARGS|,
      *         |WifiStatusCode.FAILURE_UNKNOWN|
      * @return channels List of channels represented by |WifiUsableChannel|
      *         Each entry represents a channel frequency, bandwidth and
      *         bitmask of modes (e.g. STA, SAP, CLI, GO, TDLS, NAN) that are
      *         allowed on that channel. E.g. If only STA mode can be supported
      *         on an indoor channel, only the IFACE_MODE_STA bit would be set
      *         for that channel. If 5GHz SAP cannot be supported, then none of
      *         the 5GHz channels will have IFACE_MODE_SOFTAP bit set.
      *         Note: Bits do not represent concurrency state. Each bit only
      *         represents whether particular mode is allowed on that channel.
      */
     getUsableChannels_1_6(WifiBand band, bitfield<WifiIfaceMode> ifaceModeMask,
         bitfield<UsableChannelFilter> filterMask)
         generates (WifiStatus status, vec<WifiUsableChannel> channels);

     /**
      * Set of interface concurrency types with the maximum number of interfaces that can have
      * one of the specified concurrency types for a given ChipConcurrencyCombination. See
      * ChipConcurrencyCombination for examples.
      */
     struct ChipConcurrencyCombinationLimit {
         // Each IfaceConcurrencyType must occur at most once.
         vec<IfaceConcurrencyType> types;
         uint32_t maxIfaces;
     };

     /**
      * Set of interfaces that can operate concurrently when in a given mode. See
      * ChipMode below.
      *
      * For example:
      *   [{STA} <= 2]
      *       At most two STA interfaces are supported
      *       [], [STA], [STA+STA]
      *
      *   [{STA} <= 1, {NAN} <= 1, {AP_BRIDGED} <= 1]
      *       Any combination of STA, NAN, AP_BRIDGED
      *       [], [STA], [NAN], [AP_BRIDGED], [STA+NAN], [STA+AP_BRIDGED], [NAN+AP_BRIDGED],
      *       [STA+NAN+AP_BRIDGED]
      *
      *   [{STA} <= 1, {NAN,P2P} <= 1]
      *       Optionally a STA and either NAN or P2P
      *       [], [STA], [STA+NAN], [STA+P2P], [NAN], [P2P]
      *       Not included [NAN+P2P], [STA+NAN+P2P]
      *
      *   [{STA} <= 1, {STA,NAN} <= 1]
      *       Optionally a STA and either a second STA or a NAN
      *       [], [STA], [STA+NAN], [STA+STA], [NAN]
      *       Not included [STA+STA+NAN]
      */
     struct ChipConcurrencyCombination {
         vec<ChipConcurrencyCombinationLimit> limits;
     };

     /**
      * A mode that the chip can be put in. A mode defines a set of constraints on
      * the interfaces that can exist while in that mode. Modes define a unit of
      * configuration where all interfaces must be torn down to switch to a
      * different mode. Some HALs may only have a single mode, but an example where
      * multiple modes would be required is if a chip has different firmwares with
      * different capabilities.
      *
      * When in a mode, it must be possible to perform any combination of creating
      * and removing interfaces as long as at least one of the
      * ChipConcurrencyCombinations is satisfied. This means that if a chip has two
      * available combinations, [{STA} <= 1] and [{AP_BRIDGED} <= 1] then it is expected
      * that exactly one STA type or one AP_BRIDGED type can be created, but it
      * is not expected that both a STA and AP_BRIDGED type  could be created. If it
      * was then there would be a single available combination
      * [{STA} <=1, {AP_BRIDGED} <= 1].
      *
      * When switching between two available combinations it is expected that
      * interfaces only supported by the initial combination must be removed until
      * the target combination is also satisfied. At that point new interfaces
      * satisfying only the target combination can be added (meaning the initial
      * combination limits will no longer satisfied). The addition of these new
      * interfaces must not impact the existence of interfaces that satisfy both
      * combinations.
      *
      * For example, a chip with available combinations:
      *     [{STA} <= 2, {NAN} <=1] and [{STA} <=1, {NAN} <= 1, {AP_BRIDGED} <= 1}]
      * If the chip currently has 3 interfaces STA, STA and NAN and wants to add an
      * AP_BRIDGED interface in place of one of the STAs then first one of the STA
      * interfaces must be removed and then the AP interface can be created after
      * the STA had been torn down. During this process the remaining STA and NAN
      * interfaces must not be removed/recreated.
      *
      * If a chip does not support this kind of reconfiguration in this mode then
      * the combinations must be separated into two separate modes. Before
      * switching modes all interfaces must be torn down, the mode switch must be
      * enacted and when it completes the new interfaces must be brought up.
      */
     struct ChipMode {
         /**
          * Id that can be used to put the chip in this mode.
          */
         ChipModeId id;

         /**
          * A list of the possible interface concurrency type combinations that the chip can have
          * while in this mode.
          */
         vec<ChipConcurrencyCombination> availableCombinations;
     };

     /**
      * Get the set of operation modes that the chip supports.
      *
      * @return status WifiStatus of the operation.
      *         Possible status codes:
      *         |WifiStatusCode.SUCCESS|,
      *         |WifiStatusCode.ERROR_WIFI_CHIP_INVALID|
      * @return modes List of modes supported by the device.
      */
     getAvailableModes_1_6() generates (WifiStatus status, vec<ChipMode> modes);

     /**
      * Retrieve the list of all the possible radio combinations supported by this
      * chip.
      *
      * @return status WifiStatus of the operation.
      *         Possible status codes:
      *         |WifiStatusCode.SUCCESS|,
      *         |WifiStatusCode.ERROR_WIFI_CHIP_INVALID|,
      *         |WifiStatusCode.ERROR_NOT_SUPPORTED|,
      *         |WifiStatusCode.FAILURE_UNKNOWN|
      * @return radioCombinationMatrix
      *         A list of all the possible radio combinations represented by
      *         |WifiRadioCombinationMatrix|.
      *         For Example in case of a chip which has two radios, where one radio is
      *         capable of 2.4GHz 2X2 only and another radio which is capable of either
      *         5GHz or 6GHz 2X2, number of possible radio combinations in this case
      *         are 5 and possible combinations are
      *         {{{2G 2X2}}, //Standalone 2G
      *         {{5G 2X2}}, //Standalone 5G
      *         {{6G 2X2}}, //Standalone 6G
      *         {{2G 2X2}, {5G 2X2}}, //2G+5G DBS
      *         {{2G 2X2}, {6G 2X2}}} //2G+6G DBS
      *         Note: Since this chip doesn’t support 5G+6G simultaneous operation
      *         as there is only one radio which can support both bands, So it can only
      *         do MCC 5G+6G. This table should not get populated with possible MCC
      *         configurations. This is only for simultaneous radio configurations
      *         (such as standalone, multi band simultaneous or single band simultaneous).
      */
     getSupportedRadioCombinationsMatrix()
         generates (WifiStatus status, WifiRadioCombinationMatrix radioCombinationMatrix);
 };
	/*
	* Copyright 2022 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	package android.hardware.wifi@1.6;

	import @1.0::ChipModeId;
	import @1.0::IWifiIface;
	import @1.0::WifiStatus;
	import @1.5::WifiBand;
	import @1.5::IWifiChip;
	import @1.5::WifiIfaceMode;
	import IWifiRttController;

	/**
	* Interface that represents a chip that must be configured as a single unit.
	*/
	interface IWifiChip extends @1.5::IWifiChip {
	/**
	* Usable Wifi channels filter masks.
	*/
	enum UsableChannelFilter : @1.5::IWifiChip.UsableChannelFilter {
	/**
	* Filter Wifi channels that are supported for NAN3.1 Instant communication mode. This
	* filter should only be applied to NAN interface.
	* - If 5G is supported default discovery channel 149/44 is considered,
	* - If 5G is not supported then channel 6 has to be considered.
	*/
	NAN_INSTANT_MODE = 1 << 2,
	};

	/**
	* Create a RTTController instance.
	*
	* RTT controller can be either:
	* a) Bound to a specific iface by passing in the corresponding \|IWifiIface\|
	* object in \|iface\| param, OR
	* b) Let the implementation decide the iface to use for RTT operations by
	* passing null in \|iface\| param.
	*
	* @param boundIface HIDL interface object representing the iface if
	* the responder must be bound to a specific iface, null otherwise.
	* @return status WifiStatus of the operation.
	* Possible status codes:
	* \|WifiStatusCode.SUCCESS\|,
	* \|WifiStatusCode.ERROR_WIFI_CHIP_INVALID\|
	*/
	createRttController_1_6(IWifiIface boundIface)
	generates (WifiStatus status, IWifiRttController rtt);

	/**
	* Retrieve list of usable Wifi channels for the specified band &
	* operational modes.
	*
	* The list of usable Wifi channels in a given band depends on factors
	* like current country code, operational mode (e.g. STA, SAP, WFD-CLI,
	* WFD-GO, TDLS, NAN) and other restrictons due to DFS, cellular coexistence
	* and conncurency state of the device.
	*
	* @param band \|WifiBand\| for which list of usable channels is requested.
	* @param ifaceModeMask Bitmask of the modes represented by \|WifiIfaceMode\|
	* Bitmask respresents all the modes that the caller is interested
	* in (e.g. STA, SAP, CLI, GO, TDLS, NAN). E.g. If the caller is
	* interested in knowing usable channels for P2P CLI, P2P GO & NAN,
	* ifaceModeMask would be set to
	* IFACE_MODE_P2P_CLIENT\|IFACE_MODE_P2P_GO\|IFACE_MODE_NAN.
	* @param filterMask Bitmask of filters represented by
	* \|UsableChannelFilter\|. Specifies whether driver should filter
	* channels based on additional criteria. If no filter is specified
	* driver should return usable channels purely based on regulatory
	* constraints.
	* @return status WifiStatus of the operation.
	* Possible status codes:
	* \|WifiStatusCode.SUCCESS\|,
	* \|WifiStatusCode.ERROR_NOT_SUPPORTED\|,
	* \|WifiStatusCode.ERROR_INVALID_ARGS\|,
	* \|WifiStatusCode.FAILURE_UNKNOWN\|
	* @return channels List of channels represented by \|WifiUsableChannel\|
	* Each entry represents a channel frequency, bandwidth and
	* bitmask of modes (e.g. STA, SAP, CLI, GO, TDLS, NAN) that are
	* allowed on that channel. E.g. If only STA mode can be supported
	* on an indoor channel, only the IFACE_MODE_STA bit would be set
	* for that channel. If 5GHz SAP cannot be supported, then none of
	* the 5GHz channels will have IFACE_MODE_SOFTAP bit set.
	* Note: Bits do not represent concurrency state. Each bit only
	* represents whether particular mode is allowed on that channel.
	*/
	getUsableChannels_1_6(WifiBand band, bitfield<WifiIfaceMode> ifaceModeMask,
	bitfield<UsableChannelFilter> filterMask)
	generates (WifiStatus status, vec<WifiUsableChannel> channels);

	/**
	* Set of interface concurrency types with the maximum number of interfaces that can have
	* one of the specified concurrency types for a given ChipConcurrencyCombination. See
	* ChipConcurrencyCombination for examples.
	*/
	struct ChipConcurrencyCombinationLimit {
	// Each IfaceConcurrencyType must occur at most once.
	vec<IfaceConcurrencyType> types;
	uint32_t maxIfaces;
	};

	/**
	* Set of interfaces that can operate concurrently when in a given mode. See
	* ChipMode below.
	*
	* For example:
	* [{STA} <= 2]
	* At most two STA interfaces are supported
	* [], [STA], [STA+STA]
	*
	* [{STA} <= 1, {NAN} <= 1, {AP_BRIDGED} <= 1]
	* Any combination of STA, NAN, AP_BRIDGED
	* [], [STA], [NAN], [AP_BRIDGED], [STA+NAN], [STA+AP_BRIDGED], [NAN+AP_BRIDGED],
	* [STA+NAN+AP_BRIDGED]
	*
	* [{STA} <= 1, {NAN,P2P} <= 1]
	* Optionally a STA and either NAN or P2P
	* [], [STA], [STA+NAN], [STA+P2P], [NAN], [P2P]
	* Not included [NAN+P2P], [STA+NAN+P2P]
	*
	* [{STA} <= 1, {STA,NAN} <= 1]
	* Optionally a STA and either a second STA or a NAN
	* [], [STA], [STA+NAN], [STA+STA], [NAN]
	* Not included [STA+STA+NAN]
	*/
	struct ChipConcurrencyCombination {
	vec<ChipConcurrencyCombinationLimit> limits;
	};

	/**
	* A mode that the chip can be put in. A mode defines a set of constraints on
	* the interfaces that can exist while in that mode. Modes define a unit of
	* configuration where all interfaces must be torn down to switch to a
	* different mode. Some HALs may only have a single mode, but an example where
	* multiple modes would be required is if a chip has different firmwares with
	* different capabilities.
	*
	* When in a mode, it must be possible to perform any combination of creating
	* and removing interfaces as long as at least one of the
	* ChipConcurrencyCombinations is satisfied. This means that if a chip has two
	* available combinations, [{STA} <= 1] and [{AP_BRIDGED} <= 1] then it is expected
	* that exactly one STA type or one AP_BRIDGED type can be created, but it
	* is not expected that both a STA and AP_BRIDGED type could be created. If it
	* was then there would be a single available combination
	* [{STA} <=1, {AP_BRIDGED} <= 1].
	*
	* When switching between two available combinations it is expected that
	* interfaces only supported by the initial combination must be removed until
	* the target combination is also satisfied. At that point new interfaces
	* satisfying only the target combination can be added (meaning the initial
	* combination limits will no longer satisfied). The addition of these new
	* interfaces must not impact the existence of interfaces that satisfy both
	* combinations.
	*
	* For example, a chip with available combinations:
	* [{STA} <= 2, {NAN} <=1] and [{STA} <=1, {NAN} <= 1, {AP_BRIDGED} <= 1}]
	* If the chip currently has 3 interfaces STA, STA and NAN and wants to add an
	* AP_BRIDGED interface in place of one of the STAs then first one of the STA
	* interfaces must be removed and then the AP interface can be created after
	* the STA had been torn down. During this process the remaining STA and NAN
	* interfaces must not be removed/recreated.
	*
	* If a chip does not support this kind of reconfiguration in this mode then
	* the combinations must be separated into two separate modes. Before
	* switching modes all interfaces must be torn down, the mode switch must be
	* enacted and when it completes the new interfaces must be brought up.
	*/
	struct ChipMode {
	/**
	* Id that can be used to put the chip in this mode.
	*/
	ChipModeId id;

	/**
	* A list of the possible interface concurrency type combinations that the chip can have
	* while in this mode.
	*/
	vec<ChipConcurrencyCombination> availableCombinations;
	};

	/**
	* Get the set of operation modes that the chip supports.
	*
	* @return status WifiStatus of the operation.
	* Possible status codes:
	* \|WifiStatusCode.SUCCESS\|,
	* \|WifiStatusCode.ERROR_WIFI_CHIP_INVALID\|
	* @return modes List of modes supported by the device.
	*/
	getAvailableModes_1_6() generates (WifiStatus status, vec<ChipMode> modes);

	/**
	* Retrieve the list of all the possible radio combinations supported by this
	* chip.
	*
	* @return status WifiStatus of the operation.
	* Possible status codes:
	* \|WifiStatusCode.SUCCESS\|,
	* \|WifiStatusCode.ERROR_WIFI_CHIP_INVALID\|,
	* \|WifiStatusCode.ERROR_NOT_SUPPORTED\|,
	* \|WifiStatusCode.FAILURE_UNKNOWN\|
	* @return radioCombinationMatrix
	* A list of all the possible radio combinations represented by
	* \|WifiRadioCombinationMatrix\|.
	* For Example in case of a chip which has two radios, where one radio is
	* capable of 2.4GHz 2X2 only and another radio which is capable of either
	* 5GHz or 6GHz 2X2, number of possible radio combinations in this case
	* are 5 and possible combinations are
	* {{{2G 2X2}}, //Standalone 2G
	* {{5G 2X2}}, //Standalone 5G
	* {{6G 2X2}}, //Standalone 6G
	* {{2G 2X2}, {5G 2X2}}, //2G+5G DBS
	* {{2G 2X2}, {6G 2X2}}} //2G+6G DBS
	* Note: Since this chip doesn’t support 5G+6G simultaneous operation
	* as there is only one radio which can support both bands, So it can only
	* do MCC 5G+6G. This table should not get populated with possible MCC
	* configurations. This is only for simultaneous radio configurations
	* (such as standalone, multi band simultaneous or single band simultaneous).
	*/
	getSupportedRadioCombinationsMatrix()
	generates (WifiStatus status, WifiRadioCombinationMatrix radioCombinationMatrix);
	};