android/nfc/Tag.java - platform/prebuilts/fullsdk/sources/android-29 - Git at Google

 /*
  * Copyright (C) 2010 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.nfc;

 import android.annotation.UnsupportedAppUsage;
 import android.content.Context;
 import android.nfc.tech.IsoDep;
 import android.nfc.tech.MifareClassic;
 import android.nfc.tech.MifareUltralight;
 import android.nfc.tech.Ndef;
 import android.nfc.tech.NdefFormatable;
 import android.nfc.tech.NfcA;
 import android.nfc.tech.NfcB;
 import android.nfc.tech.NfcBarcode;
 import android.nfc.tech.NfcF;
 import android.nfc.tech.NfcV;
 import android.nfc.tech.TagTechnology;
 import android.os.Bundle;
 import android.os.Parcel;
 import android.os.Parcelable;
 import android.os.RemoteException;

 import java.io.IOException;
 import java.util.Arrays;
 import java.util.HashMap;

 /**
  * Represents an NFC tag that has been discovered.
  * <p>
  * {@link Tag} is an immutable object that represents the state of a NFC tag at
  * the time of discovery. It can be used as a handle to {@link TagTechnology} classes
  * to perform advanced operations, or directly queried for its ID via {@link #getId} and the
  * set of technologies it contains via {@link #getTechList}. Arrays passed to and
  * returned by this class are <em>not</em> cloned, so be careful not to modify them.
  * <p>
  * A new tag object is created every time a tag is discovered (comes into range), even
  * if it is the same physical tag. If a tag is removed and then returned into range, then
  * only the most recent tag object can be successfully used to create a {@link TagTechnology}.
  *
  * <h3>Tag Dispatch</h3>
  * When a tag is discovered, a {@link Tag} object is created and passed to a
  * single activity via the {@link NfcAdapter#EXTRA_TAG} extra in an
  * {@link android.content.Intent} via {@link Context#startActivity}. A four stage dispatch is used
  * to select the
  * most appropriate activity to handle the tag. The Android OS executes each stage in order,
  * and completes dispatch as soon as a single matching activity is found. If there are multiple
  * matching activities found at any one stage then the Android activity chooser dialog is shown
  * to allow the user to select the activity to receive the tag.
  *
  * <p>The Tag dispatch mechanism was designed to give a high probability of dispatching
  * a tag to the correct activity without showing the user an activity chooser dialog.
  * This is important for NFC interactions because they are very transient -- if a user has to
  * move the Android device to choose an application then the connection will likely be broken.
  *
  * <h4>1. Foreground activity dispatch</h4>
  * A foreground activity that has called
  * {@link NfcAdapter#enableForegroundDispatch NfcAdapter.enableForegroundDispatch()} is
  * given priority. See the documentation on
  * {@link NfcAdapter#enableForegroundDispatch NfcAdapter.enableForegroundDispatch()} for
  * its usage.
  * <h4>2. NDEF data dispatch</h4>
  * If the tag contains NDEF data the system inspects the first {@link NdefRecord} in the first
  * {@link NdefMessage}. If the record is a URI, SmartPoster, or MIME data
  * {@link Context#startActivity} is called with {@link NfcAdapter#ACTION_NDEF_DISCOVERED}. For URI
  * and SmartPoster records the URI is put into the intent's data field. For MIME records the MIME
  * type is put in the intent's type field. This allows activities to register to be launched only
  * when data they know how to handle is present on a tag. This is the preferred method of handling
  * data on a tag since NDEF data can be stored on many types of tags and doesn't depend on a
  * specific tag technology.
  * See {@link NfcAdapter#ACTION_NDEF_DISCOVERED} for more detail. If the tag does not contain
  * NDEF data, or if no activity is registered
  * for {@link NfcAdapter#ACTION_NDEF_DISCOVERED} with a matching data URI or MIME type then dispatch
  * moves to stage 3.
  * <h4>3. Tag Technology dispatch</h4>
  * {@link Context#startActivity} is called with {@link NfcAdapter#ACTION_TECH_DISCOVERED} to
  * dispatch the tag to an activity that can handle the technologies present on the tag.
  * Technologies are defined as sub-classes of {@link TagTechnology}, see the package
  * {@link android.nfc.tech}. The Android OS looks for an activity that can handle one or
  * more technologies in the tag. See {@link NfcAdapter#ACTION_TECH_DISCOVERED} for more detail.
  * <h4>4. Fall-back dispatch</h4>
  * If no activity has been matched then {@link Context#startActivity} is called with
  * {@link NfcAdapter#ACTION_TAG_DISCOVERED}. This is intended as a fall-back mechanism.
  * See {@link NfcAdapter#ACTION_TAG_DISCOVERED}.
  *
  * <h3>NFC Tag Background</h3>
  * An NFC tag is a passive NFC device, powered by the NFC field of this Android device while
  * it is in range. Tag's can come in many forms, such as stickers, cards, key fobs, or
  * even embedded in a more sophisticated device.
  * <p>
  * Tags can have a wide range of capabilities. Simple tags just offer read/write semantics,
  * and contain some one time
  * programmable areas to make read-only. More complex tags offer math operations
  * and per-sector access control and authentication. The most sophisticated tags
  * contain operating environments allowing complex interactions with the
  * code executing on the tag. Use {@link TagTechnology} classes to access a broad
  * range of capabilities available in NFC tags.
  * <p>
  */
 public final class Tag implements Parcelable {
     @UnsupportedAppUsage
     final byte[] mId;
     final int[] mTechList;
     final String[] mTechStringList;
     final Bundle[] mTechExtras;
     final int mServiceHandle;  // for use by NFC service, 0 indicates a mock
     final INfcTag mTagService; // interface to NFC service, will be null if mock tag

     int mConnectedTechnology;

     /**
      * Hidden constructor to be used by NFC service and internal classes.
      * @hide
      */
     public Tag(byte[] id, int[] techList, Bundle[] techListExtras, int serviceHandle,
             INfcTag tagService) {
         if (techList == null) {
             throw new IllegalArgumentException("rawTargets cannot be null");
         }
         mId = id;
         mTechList = Arrays.copyOf(techList, techList.length);
         mTechStringList = generateTechStringList(techList);
         // Ensure mTechExtras is as long as mTechList
         mTechExtras = Arrays.copyOf(techListExtras, techList.length);
         mServiceHandle = serviceHandle;
         mTagService = tagService;

         mConnectedTechnology = -1;
     }

     /**
      * Construct a mock Tag.
      * <p>This is an application constructed tag, so NfcAdapter methods on this Tag may fail
      * with {@link IllegalArgumentException} since it does not represent a physical Tag.
      * <p>This constructor might be useful for mock testing.
      * @param id The tag identifier, can be null
      * @param techList must not be null
      * @return freshly constructed tag
      * @hide
      */
     public static Tag createMockTag(byte[] id, int[] techList, Bundle[] techListExtras) {
         // set serviceHandle to 0 and tagService to null to indicate mock tag
         return new Tag(id, techList, techListExtras, 0, null);
     }

     private String[] generateTechStringList(int[] techList) {
         final int size = techList.length;
         String[] strings = new String[size];
         for (int i = 0; i < size; i++) {
             switch (techList[i]) {
                 case TagTechnology.ISO_DEP:
                     strings[i] = IsoDep.class.getName();
                     break;
                 case TagTechnology.MIFARE_CLASSIC:
                     strings[i] = MifareClassic.class.getName();
                     break;
                 case TagTechnology.MIFARE_ULTRALIGHT:
                     strings[i] = MifareUltralight.class.getName();
                     break;
                 case TagTechnology.NDEF:
                     strings[i] = Ndef.class.getName();
                     break;
                 case TagTechnology.NDEF_FORMATABLE:
                     strings[i] = NdefFormatable.class.getName();
                     break;
                 case TagTechnology.NFC_A:
                     strings[i] = NfcA.class.getName();
                     break;
                 case TagTechnology.NFC_B:
                     strings[i] = NfcB.class.getName();
                     break;
                 case TagTechnology.NFC_F:
                     strings[i] = NfcF.class.getName();
                     break;
                 case TagTechnology.NFC_V:
                     strings[i] = NfcV.class.getName();
                     break;
                 case TagTechnology.NFC_BARCODE:
                     strings[i] = NfcBarcode.class.getName();
                     break;
                 default:
                     throw new IllegalArgumentException("Unknown tech type " + techList[i]);
             }
         }
         return strings;
     }

     static int[] getTechCodesFromStrings(String[] techStringList) throws IllegalArgumentException {
         if (techStringList == null) {
             throw new IllegalArgumentException("List cannot be null");
         }
         int[] techIntList = new int[techStringList.length];
         HashMap<String, Integer> stringToCodeMap = getTechStringToCodeMap();
         for (int i = 0; i < techStringList.length; i++) {
             Integer code = stringToCodeMap.get(techStringList[i]);

             if (code == null) {
                 throw new IllegalArgumentException("Unknown tech type " + techStringList[i]);
             }

             techIntList[i] = code.intValue();
         }
         return techIntList;
     }

     private static HashMap<String, Integer> getTechStringToCodeMap() {
         HashMap<String, Integer> techStringToCodeMap = new HashMap<String, Integer>();

         techStringToCodeMap.put(IsoDep.class.getName(), TagTechnology.ISO_DEP);
         techStringToCodeMap.put(MifareClassic.class.getName(), TagTechnology.MIFARE_CLASSIC);
         techStringToCodeMap.put(MifareUltralight.class.getName(), TagTechnology.MIFARE_ULTRALIGHT);
         techStringToCodeMap.put(Ndef.class.getName(), TagTechnology.NDEF);
         techStringToCodeMap.put(NdefFormatable.class.getName(), TagTechnology.NDEF_FORMATABLE);
         techStringToCodeMap.put(NfcA.class.getName(), TagTechnology.NFC_A);
         techStringToCodeMap.put(NfcB.class.getName(), TagTechnology.NFC_B);
         techStringToCodeMap.put(NfcF.class.getName(), TagTechnology.NFC_F);
         techStringToCodeMap.put(NfcV.class.getName(), TagTechnology.NFC_V);
         techStringToCodeMap.put(NfcBarcode.class.getName(), TagTechnology.NFC_BARCODE);

         return techStringToCodeMap;
     }

     /**
      * For use by NfcService only.
      * @hide
      */
     @UnsupportedAppUsage
     public int getServiceHandle() {
         return mServiceHandle;
     }

     /**
      * For use by NfcService only.
      * @hide
      */
     public int[] getTechCodeList() {
         return mTechList;
     }

     /**
      * Get the Tag Identifier (if it has one).
      * <p>The tag identifier is a low level serial number, used for anti-collision
      * and identification.
      * <p> Most tags have a stable unique identifier
      * (UID), but some tags will generate a random ID every time they are discovered
      * (RID), and there are some tags with no ID at all (the byte array will be zero-sized).
      * <p> The size and format of an ID is specific to the RF technology used by the tag.
      * <p> This function retrieves the ID as determined at discovery time, and does not
      * perform any further RF communication or block.
      * @return ID as byte array, never null
      */
     public byte[] getId() {
         return mId;
     }

     /**
      * Get the technologies available in this tag, as fully qualified class names.
      * <p>
      * A technology is an implementation of the {@link TagTechnology} interface,
      * and can be instantiated by calling the static <code>get(Tag)</code>
      * method on the implementation with this Tag. The {@link TagTechnology}
      * object can then be used to perform advanced, technology-specific operations on a tag.
      * <p>
      * Android defines a mandatory set of technologies that must be correctly
      * enumerated by all Android NFC devices, and an optional
      * set of proprietary technologies.
      * See {@link TagTechnology} for more details.
      * <p>
      * The ordering of the returned array is undefined and should not be relied upon.
      * @return an array of fully-qualified {@link TagTechnology} class-names.
      */
     public String[] getTechList() {
         return mTechStringList;
     }

     /**
      * Rediscover the technologies available on this tag.
      * <p>
      * The technologies that are available on a tag may change due to
      * operations being performed on a tag. For example, formatting a
      * tag as NDEF adds the {@link Ndef} technology. The {@link rediscover}
      * method reenumerates the available technologies on the tag
      * and returns a new {@link Tag} object containing these technologies.
      * <p>
      * You may not be connected to any of this {@link Tag}'s technologies
      * when calling this method.
      * This method guarantees that you will be returned the same Tag
      * if it is still in the field.
      * <p>May cause RF activity and may block. Must not be called
      * from the main application thread. A blocked call will be canceled with
      * {@link IOException} by calling {@link #close} from another thread.
      * <p>Does not remove power from the RF field, so a tag having a random
      * ID should not change its ID.
      * @return the rediscovered tag object.
      * @throws IOException if the tag cannot be rediscovered
      * @hide
      */
     // TODO See if we need TagLostException
     // TODO Unhide for ICS
     // TODO Update documentation to make sure it matches with the final
     //      implementation.
     public Tag rediscover() throws IOException {
         if (getConnectedTechnology() != -1) {
             throw new IllegalStateException("Close connection to the technology first!");
         }

         if (mTagService == null) {
             throw new IOException("Mock tags don't support this operation.");
         }
         try {
             Tag newTag = mTagService.rediscover(getServiceHandle());
             if (newTag != null) {
                 return newTag;
             } else {
                 throw new IOException("Failed to rediscover tag");
             }
         } catch (RemoteException e) {
             throw new IOException("NFC service dead");
         }
     }


     /** @hide */
     public boolean hasTech(int techType) {
         for (int tech : mTechList) {
             if (tech == techType) return true;
         }
         return false;
     }

     /** @hide */
     public Bundle getTechExtras(int tech) {
         int pos = -1;
         for (int idx = 0; idx < mTechList.length; idx++) {
           if (mTechList[idx] == tech) {
               pos = idx;
               break;
           }
         }
         if (pos < 0) {
             return null;
         }

         return mTechExtras[pos];
     }

     /** @hide */
     @UnsupportedAppUsage
     public INfcTag getTagService() {
         return mTagService;
     }

     /**
      * Human-readable description of the tag, for debugging.
      */
     @Override
     public String toString() {
         StringBuilder sb = new StringBuilder("TAG: Tech [");
         String[] techList = getTechList();
         int length = techList.length;
         for (int i = 0; i < length; i++) {
             sb.append(techList[i]);
             if (i < length - 1) {
                 sb.append(", ");
             }
         }
         sb.append("]");
         return sb.toString();
     }

     /*package*/ static byte[] readBytesWithNull(Parcel in) {
         int len = in.readInt();
         byte[] result = null;
         if (len >= 0) {
             result = new byte[len];
             in.readByteArray(result);
         }
         return result;
     }

     /*package*/ static void writeBytesWithNull(Parcel out, byte[] b) {
         if (b == null) {
             out.writeInt(-1);
             return;
         }
         out.writeInt(b.length);
         out.writeByteArray(b);
     }

     @Override
     public int describeContents() {
         return 0;
     }

     @Override
     public void writeToParcel(Parcel dest, int flags) {
         // Null mTagService means this is a mock tag
         int isMock = (mTagService == null)?1:0;

         writeBytesWithNull(dest, mId);
         dest.writeInt(mTechList.length);
         dest.writeIntArray(mTechList);
         dest.writeTypedArray(mTechExtras, 0);
         dest.writeInt(mServiceHandle);
         dest.writeInt(isMock);
         if (isMock == 0) {
             dest.writeStrongBinder(mTagService.asBinder());
         }
     }

     public static final @android.annotation.NonNull Parcelable.Creator<Tag> CREATOR =
             new Parcelable.Creator<Tag>() {
         @Override
         public Tag createFromParcel(Parcel in) {
             INfcTag tagService;

             // Tag fields
             byte[] id = Tag.readBytesWithNull(in);
             int[] techList = new int[in.readInt()];
             in.readIntArray(techList);
             Bundle[] techExtras = in.createTypedArray(Bundle.CREATOR);
             int serviceHandle = in.readInt();
             int isMock = in.readInt();
             if (isMock == 0) {
                 tagService = INfcTag.Stub.asInterface(in.readStrongBinder());
             }
             else {
                 tagService = null;
             }

             return new Tag(id, techList, techExtras, serviceHandle, tagService);
         }

         @Override
         public Tag[] newArray(int size) {
             return new Tag[size];
         }
     };

     /**
      * For internal use only.
      *
      * @hide
      */
     public synchronized void setConnectedTechnology(int technology) {
         if (mConnectedTechnology == -1) {
             mConnectedTechnology = technology;
         } else {
             throw new IllegalStateException("Close other technology first!");
         }
     }

     /**
      * For internal use only.
      *
      * @hide
      */
     public int getConnectedTechnology() {
         return mConnectedTechnology;
     }

     /**
      * For internal use only.
      *
      * @hide
      */
     public void setTechnologyDisconnected() {
         mConnectedTechnology = -1;
     }
 }
	/*
	* Copyright (C) 2010 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.nfc;

	import android.annotation.UnsupportedAppUsage;
	import android.content.Context;
	import android.nfc.tech.IsoDep;
	import android.nfc.tech.MifareClassic;
	import android.nfc.tech.MifareUltralight;
	import android.nfc.tech.Ndef;
	import android.nfc.tech.NdefFormatable;
	import android.nfc.tech.NfcA;
	import android.nfc.tech.NfcB;
	import android.nfc.tech.NfcBarcode;
	import android.nfc.tech.NfcF;
	import android.nfc.tech.NfcV;
	import android.nfc.tech.TagTechnology;
	import android.os.Bundle;
	import android.os.Parcel;
	import android.os.Parcelable;
	import android.os.RemoteException;

	import java.io.IOException;
	import java.util.Arrays;
	import java.util.HashMap;

	/**
	* Represents an NFC tag that has been discovered.
	* <p>
	* {@link Tag} is an immutable object that represents the state of a NFC tag at
	* the time of discovery. It can be used as a handle to {@link TagTechnology} classes
	* to perform advanced operations, or directly queried for its ID via {@link #getId} and the
	* set of technologies it contains via {@link #getTechList}. Arrays passed to and
	* returned by this class are <em>not</em> cloned, so be careful not to modify them.
	* <p>
	* A new tag object is created every time a tag is discovered (comes into range), even
	* if it is the same physical tag. If a tag is removed and then returned into range, then
	* only the most recent tag object can be successfully used to create a {@link TagTechnology}.
	*
	* <h3>Tag Dispatch</h3>
	* When a tag is discovered, a {@link Tag} object is created and passed to a
	* single activity via the {@link NfcAdapter#EXTRA_TAG} extra in an
	* {@link android.content.Intent} via {@link Context#startActivity}. A four stage dispatch is used
	* to select the
	* most appropriate activity to handle the tag. The Android OS executes each stage in order,
	* and completes dispatch as soon as a single matching activity is found. If there are multiple
	* matching activities found at any one stage then the Android activity chooser dialog is shown
	* to allow the user to select the activity to receive the tag.
	*
	* <p>The Tag dispatch mechanism was designed to give a high probability of dispatching
	* a tag to the correct activity without showing the user an activity chooser dialog.
	* This is important for NFC interactions because they are very transient -- if a user has to
	* move the Android device to choose an application then the connection will likely be broken.
	*
	* <h4>1. Foreground activity dispatch</h4>
	* A foreground activity that has called
	* {@link NfcAdapter#enableForegroundDispatch NfcAdapter.enableForegroundDispatch()} is
	* given priority. See the documentation on
	* {@link NfcAdapter#enableForegroundDispatch NfcAdapter.enableForegroundDispatch()} for
	* its usage.
	* <h4>2. NDEF data dispatch</h4>
	* If the tag contains NDEF data the system inspects the first {@link NdefRecord} in the first
	* {@link NdefMessage}. If the record is a URI, SmartPoster, or MIME data
	* {@link Context#startActivity} is called with {@link NfcAdapter#ACTION_NDEF_DISCOVERED}. For URI
	* and SmartPoster records the URI is put into the intent's data field. For MIME records the MIME
	* type is put in the intent's type field. This allows activities to register to be launched only
	* when data they know how to handle is present on a tag. This is the preferred method of handling
	* data on a tag since NDEF data can be stored on many types of tags and doesn't depend on a
	* specific tag technology.
	* See {@link NfcAdapter#ACTION_NDEF_DISCOVERED} for more detail. If the tag does not contain
	* NDEF data, or if no activity is registered
	* for {@link NfcAdapter#ACTION_NDEF_DISCOVERED} with a matching data URI or MIME type then dispatch
	* moves to stage 3.
	* <h4>3. Tag Technology dispatch</h4>
	* {@link Context#startActivity} is called with {@link NfcAdapter#ACTION_TECH_DISCOVERED} to
	* dispatch the tag to an activity that can handle the technologies present on the tag.
	* Technologies are defined as sub-classes of {@link TagTechnology}, see the package
	* {@link android.nfc.tech}. The Android OS looks for an activity that can handle one or
	* more technologies in the tag. See {@link NfcAdapter#ACTION_TECH_DISCOVERED} for more detail.
	* <h4>4. Fall-back dispatch</h4>
	* If no activity has been matched then {@link Context#startActivity} is called with
	* {@link NfcAdapter#ACTION_TAG_DISCOVERED}. This is intended as a fall-back mechanism.
	* See {@link NfcAdapter#ACTION_TAG_DISCOVERED}.
	*
	* <h3>NFC Tag Background</h3>
	* An NFC tag is a passive NFC device, powered by the NFC field of this Android device while
	* it is in range. Tag's can come in many forms, such as stickers, cards, key fobs, or
	* even embedded in a more sophisticated device.
	* <p>
	* Tags can have a wide range of capabilities. Simple tags just offer read/write semantics,
	* and contain some one time
	* programmable areas to make read-only. More complex tags offer math operations
	* and per-sector access control and authentication. The most sophisticated tags
	* contain operating environments allowing complex interactions with the
	* code executing on the tag. Use {@link TagTechnology} classes to access a broad
	* range of capabilities available in NFC tags.
	* <p>
	*/
	public final class Tag implements Parcelable {
	@UnsupportedAppUsage
	final byte[] mId;
	final int[] mTechList;
	final String[] mTechStringList;
	final Bundle[] mTechExtras;
	final int mServiceHandle; // for use by NFC service, 0 indicates a mock
	final INfcTag mTagService; // interface to NFC service, will be null if mock tag

	int mConnectedTechnology;

	/**
	* Hidden constructor to be used by NFC service and internal classes.
	* @hide
	*/
	public Tag(byte[] id, int[] techList, Bundle[] techListExtras, int serviceHandle,
	INfcTag tagService) {
	if (techList == null) {
	throw new IllegalArgumentException("rawTargets cannot be null");
	}
	mId = id;
	mTechList = Arrays.copyOf(techList, techList.length);
	mTechStringList = generateTechStringList(techList);
	// Ensure mTechExtras is as long as mTechList
	mTechExtras = Arrays.copyOf(techListExtras, techList.length);
	mServiceHandle = serviceHandle;
	mTagService = tagService;

	mConnectedTechnology = -1;
	}

	/**
	* Construct a mock Tag.
	* <p>This is an application constructed tag, so NfcAdapter methods on this Tag may fail
	* with {@link IllegalArgumentException} since it does not represent a physical Tag.
	* <p>This constructor might be useful for mock testing.
	* @param id The tag identifier, can be null
	* @param techList must not be null
	* @return freshly constructed tag
	* @hide
	*/
	public static Tag createMockTag(byte[] id, int[] techList, Bundle[] techListExtras) {
	// set serviceHandle to 0 and tagService to null to indicate mock tag
	return new Tag(id, techList, techListExtras, 0, null);
	}

	private String[] generateTechStringList(int[] techList) {
	final int size = techList.length;
	String[] strings = new String[size];
	for (int i = 0; i < size; i++) {
	switch (techList[i]) {
	case TagTechnology.ISO_DEP:
	strings[i] = IsoDep.class.getName();
	break;
	case TagTechnology.MIFARE_CLASSIC:
	strings[i] = MifareClassic.class.getName();
	break;
	case TagTechnology.MIFARE_ULTRALIGHT:
	strings[i] = MifareUltralight.class.getName();
	break;
	case TagTechnology.NDEF:
	strings[i] = Ndef.class.getName();
	break;
	case TagTechnology.NDEF_FORMATABLE:
	strings[i] = NdefFormatable.class.getName();
	break;
	case TagTechnology.NFC_A:
	strings[i] = NfcA.class.getName();
	break;
	case TagTechnology.NFC_B:
	strings[i] = NfcB.class.getName();
	break;
	case TagTechnology.NFC_F:
	strings[i] = NfcF.class.getName();
	break;
	case TagTechnology.NFC_V:
	strings[i] = NfcV.class.getName();
	break;
	case TagTechnology.NFC_BARCODE:
	strings[i] = NfcBarcode.class.getName();
	break;
	default:
	throw new IllegalArgumentException("Unknown tech type " + techList[i]);
	}
	}
	return strings;
	}

	static int[] getTechCodesFromStrings(String[] techStringList) throws IllegalArgumentException {
	if (techStringList == null) {
	throw new IllegalArgumentException("List cannot be null");
	}
	int[] techIntList = new int[techStringList.length];
	HashMap<String, Integer> stringToCodeMap = getTechStringToCodeMap();
	for (int i = 0; i < techStringList.length; i++) {
	Integer code = stringToCodeMap.get(techStringList[i]);

	if (code == null) {
	throw new IllegalArgumentException("Unknown tech type " + techStringList[i]);
	}

	techIntList[i] = code.intValue();
	}
	return techIntList;
	}

	private static HashMap<String, Integer> getTechStringToCodeMap() {
	HashMap<String, Integer> techStringToCodeMap = new HashMap<String, Integer>();

	techStringToCodeMap.put(IsoDep.class.getName(), TagTechnology.ISO_DEP);
	techStringToCodeMap.put(MifareClassic.class.getName(), TagTechnology.MIFARE_CLASSIC);
	techStringToCodeMap.put(MifareUltralight.class.getName(), TagTechnology.MIFARE_ULTRALIGHT);
	techStringToCodeMap.put(Ndef.class.getName(), TagTechnology.NDEF);
	techStringToCodeMap.put(NdefFormatable.class.getName(), TagTechnology.NDEF_FORMATABLE);
	techStringToCodeMap.put(NfcA.class.getName(), TagTechnology.NFC_A);
	techStringToCodeMap.put(NfcB.class.getName(), TagTechnology.NFC_B);
	techStringToCodeMap.put(NfcF.class.getName(), TagTechnology.NFC_F);
	techStringToCodeMap.put(NfcV.class.getName(), TagTechnology.NFC_V);
	techStringToCodeMap.put(NfcBarcode.class.getName(), TagTechnology.NFC_BARCODE);

	return techStringToCodeMap;
	}

	/**
	* For use by NfcService only.
	* @hide
	*/
	@UnsupportedAppUsage
	public int getServiceHandle() {
	return mServiceHandle;
	}

	/**
	* For use by NfcService only.
	* @hide
	*/
	public int[] getTechCodeList() {
	return mTechList;
	}

	/**
	* Get the Tag Identifier (if it has one).
	* <p>The tag identifier is a low level serial number, used for anti-collision
	* and identification.
	* <p> Most tags have a stable unique identifier
	* (UID), but some tags will generate a random ID every time they are discovered
	* (RID), and there are some tags with no ID at all (the byte array will be zero-sized).
	* <p> The size and format of an ID is specific to the RF technology used by the tag.
	* <p> This function retrieves the ID as determined at discovery time, and does not
	* perform any further RF communication or block.
	* @return ID as byte array, never null
	*/
	public byte[] getId() {
	return mId;
	}

	/**
	* Get the technologies available in this tag, as fully qualified class names.
	* <p>
	* A technology is an implementation of the {@link TagTechnology} interface,
	* and can be instantiated by calling the static <code>get(Tag)</code>
	* method on the implementation with this Tag. The {@link TagTechnology}
	* object can then be used to perform advanced, technology-specific operations on a tag.
	* <p>
	* Android defines a mandatory set of technologies that must be correctly
	* enumerated by all Android NFC devices, and an optional
	* set of proprietary technologies.
	* See {@link TagTechnology} for more details.
	* <p>
	* The ordering of the returned array is undefined and should not be relied upon.
	* @return an array of fully-qualified {@link TagTechnology} class-names.
	*/
	public String[] getTechList() {
	return mTechStringList;
	}

	/**
	* Rediscover the technologies available on this tag.
	* <p>
	* The technologies that are available on a tag may change due to
	* operations being performed on a tag. For example, formatting a
	* tag as NDEF adds the {@link Ndef} technology. The {@link rediscover}
	* method reenumerates the available technologies on the tag
	* and returns a new {@link Tag} object containing these technologies.
	* <p>
	* You may not be connected to any of this {@link Tag}'s technologies
	* when calling this method.
	* This method guarantees that you will be returned the same Tag
	* if it is still in the field.
	* <p>May cause RF activity and may block. Must not be called
	* from the main application thread. A blocked call will be canceled with
	* {@link IOException} by calling {@link #close} from another thread.
	* <p>Does not remove power from the RF field, so a tag having a random
	* ID should not change its ID.
	* @return the rediscovered tag object.
	* @throws IOException if the tag cannot be rediscovered
	* @hide
	*/
	// TODO See if we need TagLostException
	// TODO Unhide for ICS
	// TODO Update documentation to make sure it matches with the final
	// implementation.
	public Tag rediscover() throws IOException {
	if (getConnectedTechnology() != -1) {
	throw new IllegalStateException("Close connection to the technology first!");
	}

	if (mTagService == null) {
	throw new IOException("Mock tags don't support this operation.");
	}
	try {
	Tag newTag = mTagService.rediscover(getServiceHandle());
	if (newTag != null) {
	return newTag;
	} else {
	throw new IOException("Failed to rediscover tag");
	}
	} catch (RemoteException e) {
	throw new IOException("NFC service dead");
	}
	}


	/** @hide */
	public boolean hasTech(int techType) {
	for (int tech : mTechList) {
	if (tech == techType) return true;
	}
	return false;
	}

	/** @hide */
	public Bundle getTechExtras(int tech) {
	int pos = -1;
	for (int idx = 0; idx < mTechList.length; idx++) {
	if (mTechList[idx] == tech) {
	pos = idx;
	break;
	}
	}
	if (pos < 0) {
	return null;
	}

	return mTechExtras[pos];
	}

	/** @hide */
	@UnsupportedAppUsage
	public INfcTag getTagService() {
	return mTagService;
	}

	/**
	* Human-readable description of the tag, for debugging.
	*/
	@Override
	public String toString() {
	StringBuilder sb = new StringBuilder("TAG: Tech [");
	String[] techList = getTechList();
	int length = techList.length;
	for (int i = 0; i < length; i++) {
	sb.append(techList[i]);
	if (i < length - 1) {
	sb.append(", ");
	}
	}
	sb.append("]");
	return sb.toString();
	}

	/package/ static byte[] readBytesWithNull(Parcel in) {
	int len = in.readInt();
	byte[] result = null;
	if (len >= 0) {
	result = new byte[len];
	in.readByteArray(result);
	}
	return result;
	}

	/package/ static void writeBytesWithNull(Parcel out, byte[] b) {
	if (b == null) {
	out.writeInt(-1);
	return;
	}
	out.writeInt(b.length);
	out.writeByteArray(b);
	}

	@Override
	public int describeContents() {
	return 0;
	}

	@Override
	public void writeToParcel(Parcel dest, int flags) {
	// Null mTagService means this is a mock tag
	int isMock = (mTagService == null)?1:0;

	writeBytesWithNull(dest, mId);
	dest.writeInt(mTechList.length);
	dest.writeIntArray(mTechList);
	dest.writeTypedArray(mTechExtras, 0);
	dest.writeInt(mServiceHandle);
	dest.writeInt(isMock);
	if (isMock == 0) {
	dest.writeStrongBinder(mTagService.asBinder());
	}
	}

	public static final @android.annotation.NonNull Parcelable.Creator<Tag> CREATOR =
	new Parcelable.Creator<Tag>() {
	@Override
	public Tag createFromParcel(Parcel in) {
	INfcTag tagService;

	// Tag fields
	byte[] id = Tag.readBytesWithNull(in);
	int[] techList = new int[in.readInt()];
	in.readIntArray(techList);
	Bundle[] techExtras = in.createTypedArray(Bundle.CREATOR);
	int serviceHandle = in.readInt();
	int isMock = in.readInt();
	if (isMock == 0) {
	tagService = INfcTag.Stub.asInterface(in.readStrongBinder());
	}
	else {
	tagService = null;
	}

	return new Tag(id, techList, techExtras, serviceHandle, tagService);
	}

	@Override
	public Tag[] newArray(int size) {
	return new Tag[size];
	}
	};

	/**
	* For internal use only.
	*
	* @hide
	*/
	public synchronized void setConnectedTechnology(int technology) {
	if (mConnectedTechnology == -1) {
	mConnectedTechnology = technology;
	} else {
	throw new IllegalStateException("Close other technology first!");
	}
	}

	/**
	* For internal use only.
	*
	* @hide
	*/
	public int getConnectedTechnology() {
	return mConnectedTechnology;
	}

	/**
	* For internal use only.
	*
	* @hide
	*/
	public void setTechnologyDisconnected() {
	mConnectedTechnology = -1;
	}
	}