wifi/1.0/IWifiChip.hal - platform_hardware_interfaces - Gitiles

 /*
  * Copyright 2016 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@1.0;

 import IWifiChipEventCallback;
 import IWifiIface;
 import IWifiApIface;
 import IWifiNanIface;
 import IWifiP2pIface;
 import IWifiStaIface;
 import IWifiRttController;

 /**
  * Interface that represents a chip that must be configured as a single unit.
  * The HAL/driver/firmware will be responsible for determining which phy is used
  * to perform operations like NAN, RTT, etc.
  */
 interface IWifiChip {
   /**
    * Set of interface types with the maximum number of interfaces that can have
    * one of the specified type for a given ChipIfaceCombination. See
    * ChipIfaceCombination for examples.
    */
   struct ChipIfaceCombinationLimit {
     vec<IfaceType> types; // Each IfaceType may occur at most once
     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} <= 1]
    *       Any combination of STA, NAN, AP
    *       [], [STA], [NAN], [AP], [STA+NAN], [STA+AP], [NAN+AP], [STA+NAN+AP]
    *
    *   [{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 ChipIfaceCombination {
     vec<ChipIfaceCombinationLimit> 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
    * ChipIfaceCombinations is satisfied. This means that if a chip has two
    * available combinations, [{STA} <= 1] and [{AP} <= 1] then it is expected
    * that exactly one STA interface or one AP interface can be created, but it
    * is not expected that both a STA and AP interface could be created. If it
    * was then there would be a single available combination
    * [{STA} <=1, {AP} <= 1].
    *
    * When switching between two available combinations it is expected that
    * interfaces only supported by the initial combination will 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 should 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} <= 1}]
    * If the chip currently has 3 interfaces STA, STA and NAN and wants to add an
    * AP 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 should not be removed/recreated.
    *
    * If a chip does not support this kind of reconfiguration in this mode then
    * the combinations should be separated into two separate modes. Before
    * switching modes all interfaces will be torn down, the mode switch will be
    * enacted and when it completes the new interfaces will 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 combinations that the chip can have
      * while in this mode.
      */
     vec<ChipIfaceCombination> availableCombinations;
   };

   /**
    * Get the id assigned to this chip.
    *
    * @return id Assigned chip Id.
    */
   getId() generates (ChipId id);

   /**
    * Requests notifications of significant events on this chip. Multiple calls
    * to this will register multiple callbacks each of which will receive all
    * events.
    *
    * @param callback An instance of the |IWifiChipEventCallback| HIDL interface
    *        object.
    */
   oneway registerEventCallback(IWifiChipEventCallback callback);

   /**
    * Get the set of operation modes that the chip supports.
    *
    * @return modes List of modes supported by the device.
    */
   getAvailableModes() generates (vec<ChipMode> modes);

   /**
    * Reconfigure the Chip.
    * Must trigger |IWifiChipEventCallback.onChipReconfigured| on sucess,
    * or |IWifiChipEventCallback.onChipReconfigureFailure| on failure.
    *
    * @param modeId The mode that the chip should switch to, corresponding to the
    *        id property of the target ChipMode.
    */
   oneway configureChip(ChipModeId modeId);

   /**
    * Get the current mode that the chip is in.
    *
    * @return modeId The mode that the chip is currently configured to,
    *         corresponding to the id property of the target ChipMode.
    */
   getMode() generates (ChipModeId modeId);

   /**
    * Request information about the chip.
    * Must trigger |IWifiChipEventCallback.onChipDebugInfoAvailable| on sucess,
    * or |IWifiChipEventCallback.onChipDebugInfoFailure| on failure.
    */
   oneway requestChipDebugInfo();

   /**
    * Request vendor debug info from the driver.
    * Must trigger |IWifiChipEventCallback.onDriverDebugDumpAvailable| on success,
    * or |IWifiChipEventCallback.onDriverDebugDumpFailure| on failure.
    */
   oneway requestDriverDebugDump();

   /**
    * Request vendor debug info from the firmware.
    * Must trigger |IWifiChipEventCallback.onFirmwareDebugDumpAvailable| on
    * success, or |IWifiChipEventCallback.onFirmwareDebugDumpFailure| on failure.
    */
   oneway requestFirmwareDebugDump();

   /**
    * Create an AP iface on the chip.
    *
    * Depending on the mode the chip is configured in, the interface creation
    * may fail if we've already reached the maximum allowed
    * (specified in |ChipIfaceCombination|) number of ifaces of the AP type.
    *
    * @return iface HIDL interface object representing the iface if
    *         successful, null otherwise.
    */
   createApIface() generates (IWifiApIface iface);

   /**
    * List all the AP iface names configured on the chip.
    * The corresponding |IWifiApIface| object for any iface are
    * retrieved using |getApIface| method.
    *
    * @return ifnames List of all AP iface names on the chip.
    */
   getApIfaceNames() generates (vec<string> ifnames);

   /**
    * Gets a HIDL interface object for the AP Iface corresponding
    * to the provided ifname.
    *
    * @param ifname Name of the iface.
    * @return iface HIDL interface object representing the iface if
    *         it exists, null otherwise.
    */
   getApIface(string ifname) generates (IWifiApIface iface);

   /**
    * Create a NAN iface on the chip.
    *
    * Depending on the mode the chip is configured in, the interface creation
    * may fail if we've already reached the maximum allowed
    * (specified in |ChipIfaceCombination|) number of ifaces of the NAN type.
    *
    * @return iface HIDL interface object representing the iface if
    *         successful, null otherwise.
    */
   createNanIface() generates (IWifiNanIface iface);

   /**
    * List all the NAN iface names configured on the chip.
    * The corresponding |IWifiNanIface| object for any iface are
    * retrieved using |getNanIface| method.
    *
    * @return ifnames List of all NAN iface names on the chip.
    */
   getNanIfaceNames() generates (vec<string> ifnames);

   /**
    * Gets a HIDL interface object for the NAN Iface corresponding
    * to the provided ifname.
    *
    * @param ifname Name of the iface.
    * @return iface HIDL interface object representing the iface if
    *         it exists, null otherwise.
    */
   getNanIface(string ifname) generates (IWifiNanIface iface);

   /**
    * Create a P2P iface on the chip.
    *
    * Depending on the mode the chip is configured in, the interface creation
    * may fail if we've already reached the maximum allowed
    * (specified in |ChipIfaceCombination|) number of ifaces of the P2P type.
    *
    * @return iface HIDL interface object representing the iface if
    *         successful, null otherwise.
    */
   createP2pIface() generates (IWifiP2pIface iface);

   /**
    * List all the P2P iface names configured on the chip.
    * The corresponding |IWifiP2pIface| object for any iface are
    * retrieved using |getP2pIface| method.
    *
    * @return ifnames List of all P2P iface names on the chip.
    */
   getP2pIfaceNames() generates (vec<string> ifnames);

   /**
    * Gets a HIDL interface object for the P2P Iface corresponding
    * to the provided ifname.
    *
    * @param ifname Name of the iface.
    * @return iface HIDL interface object representing the iface if
    *         it exists, null otherwise.
    */
   getP2pIface(string ifname) generates (IWifiP2pIface iface);

   /**
    * Create an STA iface on the chip.
    *
    * Depending on the mode the chip is configured in, the interface creation
    * may fail if we've already reached the maximum allowed
    * (specified in |ChipIfaceCombination|) number of ifaces of the STA type.
    *
    * @return iface HIDL interface object representing the iface if
    *         successful, null otherwise.
    */
   createStaIface() generates (IWifiStaIface iface);

   /**
    * List all the STA iface names configured on the chip.
    * The corresponding |IWifiStaIface| object for any iface are
    * retrieved using |getStaIface| method.
    *
    * @return ifnames List of all STA iface names on the chip.
    */
   getStaIfaceNames() generates (vec<string> ifnames);

   /**
    * Gets a HIDL interface object for the STA Iface corresponding
    * to the provided ifname.
    *
    * @param ifname Name of the iface.
    * @return iface HIDL interface object representing the iface if
    *         it exists, null otherwise.
    */
   getStaIface(string ifname) generates (IWifiStaIface iface);

   /**
    * 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.
    */
   createRttController(IWifiIface boundIface) generates (IWifiRttController rtt);
 };
	/*
	* Copyright 2016 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@1.0;

	import IWifiChipEventCallback;
	import IWifiIface;
	import IWifiApIface;
	import IWifiNanIface;
	import IWifiP2pIface;
	import IWifiStaIface;
	import IWifiRttController;

	/**
	* Interface that represents a chip that must be configured as a single unit.
	* The HAL/driver/firmware will be responsible for determining which phy is used
	* to perform operations like NAN, RTT, etc.
	*/
	interface IWifiChip {
	/**
	* Set of interface types with the maximum number of interfaces that can have
	* one of the specified type for a given ChipIfaceCombination. See
	* ChipIfaceCombination for examples.
	*/
	struct ChipIfaceCombinationLimit {
	vec<IfaceType> types; // Each IfaceType may occur at most once
	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} <= 1]
	* Any combination of STA, NAN, AP
	* [], [STA], [NAN], [AP], [STA+NAN], [STA+AP], [NAN+AP], [STA+NAN+AP]
	*
	* [{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 ChipIfaceCombination {
	vec<ChipIfaceCombinationLimit> 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
	* ChipIfaceCombinations is satisfied. This means that if a chip has two
	* available combinations, [{STA} <= 1] and [{AP} <= 1] then it is expected
	* that exactly one STA interface or one AP interface can be created, but it
	* is not expected that both a STA and AP interface could be created. If it
	* was then there would be a single available combination
	* [{STA} <=1, {AP} <= 1].
	*
	* When switching between two available combinations it is expected that
	* interfaces only supported by the initial combination will 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 should 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} <= 1}]
	* If the chip currently has 3 interfaces STA, STA and NAN and wants to add an
	* AP 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 should not be removed/recreated.
	*
	* If a chip does not support this kind of reconfiguration in this mode then
	* the combinations should be separated into two separate modes. Before
	* switching modes all interfaces will be torn down, the mode switch will be
	* enacted and when it completes the new interfaces will 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 combinations that the chip can have
	* while in this mode.
	*/
	vec<ChipIfaceCombination> availableCombinations;
	};

	/**
	* Get the id assigned to this chip.
	*
	* @return id Assigned chip Id.
	*/
	getId() generates (ChipId id);

	/**
	* Requests notifications of significant events on this chip. Multiple calls
	* to this will register multiple callbacks each of which will receive all
	* events.
	*
	* @param callback An instance of the \|IWifiChipEventCallback\| HIDL interface
	* object.
	*/
	oneway registerEventCallback(IWifiChipEventCallback callback);

	/**
	* Get the set of operation modes that the chip supports.
	*
	* @return modes List of modes supported by the device.
	*/
	getAvailableModes() generates (vec<ChipMode> modes);

	/**
	* Reconfigure the Chip.
	* Must trigger \|IWifiChipEventCallback.onChipReconfigured\| on sucess,
	* or \|IWifiChipEventCallback.onChipReconfigureFailure\| on failure.
	*
	* @param modeId The mode that the chip should switch to, corresponding to the
	* id property of the target ChipMode.
	*/
	oneway configureChip(ChipModeId modeId);

	/**
	* Get the current mode that the chip is in.
	*
	* @return modeId The mode that the chip is currently configured to,
	* corresponding to the id property of the target ChipMode.
	*/
	getMode() generates (ChipModeId modeId);

	/**
	* Request information about the chip.
	* Must trigger \|IWifiChipEventCallback.onChipDebugInfoAvailable\| on sucess,
	* or \|IWifiChipEventCallback.onChipDebugInfoFailure\| on failure.
	*/
	oneway requestChipDebugInfo();

	/**
	* Request vendor debug info from the driver.
	* Must trigger \|IWifiChipEventCallback.onDriverDebugDumpAvailable\| on success,
	* or \|IWifiChipEventCallback.onDriverDebugDumpFailure\| on failure.
	*/
	oneway requestDriverDebugDump();

	/**
	* Request vendor debug info from the firmware.
	* Must trigger \|IWifiChipEventCallback.onFirmwareDebugDumpAvailable\| on
	* success, or \|IWifiChipEventCallback.onFirmwareDebugDumpFailure\| on failure.
	*/
	oneway requestFirmwareDebugDump();

	/**
	* Create an AP iface on the chip.
	*
	* Depending on the mode the chip is configured in, the interface creation
	* may fail if we've already reached the maximum allowed
	* (specified in \|ChipIfaceCombination\|) number of ifaces of the AP type.
	*
	* @return iface HIDL interface object representing the iface if
	* successful, null otherwise.
	*/
	createApIface() generates (IWifiApIface iface);

	/**
	* List all the AP iface names configured on the chip.
	* The corresponding \|IWifiApIface\| object for any iface are
	* retrieved using \|getApIface\| method.
	*
	* @return ifnames List of all AP iface names on the chip.
	*/
	getApIfaceNames() generates (vec<string> ifnames);

	/**
	* Gets a HIDL interface object for the AP Iface corresponding
	* to the provided ifname.
	*
	* @param ifname Name of the iface.
	* @return iface HIDL interface object representing the iface if
	* it exists, null otherwise.
	*/
	getApIface(string ifname) generates (IWifiApIface iface);

	/**
	* Create a NAN iface on the chip.
	*
	* Depending on the mode the chip is configured in, the interface creation
	* may fail if we've already reached the maximum allowed
	* (specified in \|ChipIfaceCombination\|) number of ifaces of the NAN type.
	*
	* @return iface HIDL interface object representing the iface if
	* successful, null otherwise.
	*/
	createNanIface() generates (IWifiNanIface iface);

	/**
	* List all the NAN iface names configured on the chip.
	* The corresponding \|IWifiNanIface\| object for any iface are
	* retrieved using \|getNanIface\| method.
	*
	* @return ifnames List of all NAN iface names on the chip.
	*/
	getNanIfaceNames() generates (vec<string> ifnames);

	/**
	* Gets a HIDL interface object for the NAN Iface corresponding
	* to the provided ifname.
	*
	* @param ifname Name of the iface.
	* @return iface HIDL interface object representing the iface if
	* it exists, null otherwise.
	*/
	getNanIface(string ifname) generates (IWifiNanIface iface);

	/**
	* Create a P2P iface on the chip.
	*
	* Depending on the mode the chip is configured in, the interface creation
	* may fail if we've already reached the maximum allowed
	* (specified in \|ChipIfaceCombination\|) number of ifaces of the P2P type.
	*
	* @return iface HIDL interface object representing the iface if
	* successful, null otherwise.
	*/
	createP2pIface() generates (IWifiP2pIface iface);

	/**
	* List all the P2P iface names configured on the chip.
	* The corresponding \|IWifiP2pIface\| object for any iface are
	* retrieved using \|getP2pIface\| method.
	*
	* @return ifnames List of all P2P iface names on the chip.
	*/
	getP2pIfaceNames() generates (vec<string> ifnames);

	/**
	* Gets a HIDL interface object for the P2P Iface corresponding
	* to the provided ifname.
	*
	* @param ifname Name of the iface.
	* @return iface HIDL interface object representing the iface if
	* it exists, null otherwise.
	*/
	getP2pIface(string ifname) generates (IWifiP2pIface iface);

	/**
	* Create an STA iface on the chip.
	*
	* Depending on the mode the chip is configured in, the interface creation
	* may fail if we've already reached the maximum allowed
	* (specified in \|ChipIfaceCombination\|) number of ifaces of the STA type.
	*
	* @return iface HIDL interface object representing the iface if
	* successful, null otherwise.
	*/
	createStaIface() generates (IWifiStaIface iface);

	/**
	* List all the STA iface names configured on the chip.
	* The corresponding \|IWifiStaIface\| object for any iface are
	* retrieved using \|getStaIface\| method.
	*
	* @return ifnames List of all STA iface names on the chip.
	*/
	getStaIfaceNames() generates (vec<string> ifnames);

	/**
	* Gets a HIDL interface object for the STA Iface corresponding
	* to the provided ifname.
	*
	* @param ifname Name of the iface.
	* @return iface HIDL interface object representing the iface if
	* it exists, null otherwise.
	*/
	getStaIface(string ifname) generates (IWifiStaIface iface);

	/**
	* 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.
	*/
	createRttController(IWifiIface boundIface) generates (IWifiRttController rtt);
	};