com/android/server/hdmi/HdmiUtils.java - platform/prebuilts/fullsdk/sources/android-29 - Git at Google

 /*
  * Copyright (C) 2014 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 com.android.server.hdmi;

 import android.annotation.Nullable;
 import android.hardware.hdmi.HdmiDeviceInfo;
 import android.util.Slog;
 import android.util.SparseArray;
 import android.util.Xml;

 import com.android.internal.util.HexDump;
 import com.android.internal.util.IndentingPrintWriter;
 import com.android.server.hdmi.Constants.AudioCodec;

 import org.xmlpull.v1.XmlPullParser;
 import org.xmlpull.v1.XmlPullParserException;

 import java.io.IOException;
 import java.io.InputStream;
 import java.util.ArrayList;
 import java.util.Arrays;
 import java.util.Collections;
 import java.util.List;
 import java.util.Map;
 import java.util.Objects;

 /**
  * Various utilities to handle HDMI CEC messages.
  */
 final class HdmiUtils {

     private static final String TAG = "HdmiUtils";

     private static final int[] ADDRESS_TO_TYPE = {
         HdmiDeviceInfo.DEVICE_TV,  // ADDR_TV
         HdmiDeviceInfo.DEVICE_RECORDER,  // ADDR_RECORDER_1
         HdmiDeviceInfo.DEVICE_RECORDER,  // ADDR_RECORDER_2
         HdmiDeviceInfo.DEVICE_TUNER,  // ADDR_TUNER_1
         HdmiDeviceInfo.DEVICE_PLAYBACK,  // ADDR_PLAYBACK_1
         HdmiDeviceInfo.DEVICE_AUDIO_SYSTEM,  // ADDR_AUDIO_SYSTEM
         HdmiDeviceInfo.DEVICE_TUNER,  // ADDR_TUNER_2
         HdmiDeviceInfo.DEVICE_TUNER,  // ADDR_TUNER_3
         HdmiDeviceInfo.DEVICE_PLAYBACK,  // ADDR_PLAYBACK_2
         HdmiDeviceInfo.DEVICE_RECORDER,  // ADDR_RECORDER_3
         HdmiDeviceInfo.DEVICE_TUNER,  // ADDR_TUNER_4
         HdmiDeviceInfo.DEVICE_PLAYBACK,  // ADDR_PLAYBACK_3
         HdmiDeviceInfo.DEVICE_RESERVED,
         HdmiDeviceInfo.DEVICE_RESERVED,
         HdmiDeviceInfo.DEVICE_TV,  // ADDR_SPECIFIC_USE
     };

     private static final String[] DEFAULT_NAMES = {
         "TV",
         "Recorder_1",
         "Recorder_2",
         "Tuner_1",
         "Playback_1",
         "AudioSystem",
         "Tuner_2",
         "Tuner_3",
         "Playback_2",
         "Recorder_3",
         "Tuner_4",
         "Playback_3",
         "Reserved_1",
         "Reserved_2",
         "Secondary_TV",
     };

     /**
      * Return value of {@link #getLocalPortFromPhysicalAddress(int, int)}
      */
     static final int TARGET_NOT_UNDER_LOCAL_DEVICE = -1;
     static final int TARGET_SAME_PHYSICAL_ADDRESS = 0;

     private HdmiUtils() { /* cannot be instantiated */ }

     /**
      * Check if the given logical address is valid. A logical address is valid
      * if it is one allocated for an actual device which allows communication
      * with other logical devices.
      *
      * @param address logical address
      * @return true if the given address is valid
      */
     static boolean isValidAddress(int address) {
         return (Constants.ADDR_TV <= address && address <= Constants.ADDR_SPECIFIC_USE);
     }

     /**
      * Return the device type for the given logical address.
      *
      * @param address logical address
      * @return device type for the given logical address; DEVICE_INACTIVE
      *         if the address is not valid.
      */
     static int getTypeFromAddress(int address) {
         if (isValidAddress(address)) {
             return ADDRESS_TO_TYPE[address];
         }
         return HdmiDeviceInfo.DEVICE_INACTIVE;
     }

     /**
      * Return the default device name for a logical address. This is the name
      * by which the logical device is known to others until a name is
      * set explicitly using HdmiCecService.setOsdName.
      *
      * @param address logical address
      * @return default device name; empty string if the address is not valid
      */
     static String getDefaultDeviceName(int address) {
         if (isValidAddress(address)) {
             return DEFAULT_NAMES[address];
         }
         return "";
     }

     /**
      * Verify if the given address is for the given device type.  If not it will throw
      * {@link IllegalArgumentException}.
      *
      * @param logicalAddress the logical address to verify
      * @param deviceType the device type to check
      * @throws IllegalArgumentException
      */
     static void verifyAddressType(int logicalAddress, int deviceType) {
         int actualDeviceType = getTypeFromAddress(logicalAddress);
         if (actualDeviceType != deviceType) {
             throw new IllegalArgumentException("Device type missmatch:[Expected:" + deviceType
                     + ", Actual:" + actualDeviceType);
         }
     }

     /**
      * Check if the given CEC message come from the given address.
      *
      * @param cmd the CEC message to check
      * @param expectedAddress the expected source address of the given message
      * @param tag the tag of caller module (for log message)
      * @return true if the CEC message comes from the given address
      */
     static boolean checkCommandSource(HdmiCecMessage cmd, int expectedAddress, String tag) {
         int src = cmd.getSource();
         if (src != expectedAddress) {
             Slog.w(tag, "Invalid source [Expected:" + expectedAddress + ", Actual:" + src + "]");
             return false;
         }
         return true;
     }

     /**
      * Parse the parameter block of CEC message as [System Audio Status].
      *
      * @param cmd the CEC message to parse
      * @return true if the given parameter has [ON] value
      */
     static boolean parseCommandParamSystemAudioStatus(HdmiCecMessage cmd) {
         return cmd.getParams()[0] == Constants.SYSTEM_AUDIO_STATUS_ON;
     }

     /**
      * Parse the <Report Audio Status> message and check if it is mute
      *
      * @param cmd the CEC message to parse
      * @return true if the given parameter has [MUTE]
      */
     static boolean isAudioStatusMute(HdmiCecMessage cmd) {
         byte params[] = cmd.getParams();
         return (params[0] & 0x80) == 0x80;
     }

     /**
      * Parse the <Report Audio Status> message and extract the volume
      *
      * @param cmd the CEC message to parse
      * @return device's volume. Constants.UNKNOWN_VOLUME in case it is out of range
      */
     static int getAudioStatusVolume(HdmiCecMessage cmd) {
         byte params[] = cmd.getParams();
         int volume = params[0] & 0x7F;
         if (volume < 0x00 || 0x64 < volume) {
             volume = Constants.UNKNOWN_VOLUME;
         }
         return volume;
     }

     /**
      * Convert integer array to list of {@link Integer}.
      *
      * <p>The result is immutable.
      *
      * @param is integer array
      * @return {@link List} instance containing the elements in the given array
      */
     static List<Integer> asImmutableList(final int[] is) {
         ArrayList<Integer> list = new ArrayList<>(is.length);
         for (int type : is) {
             list.add(type);
         }
         return Collections.unmodifiableList(list);
     }

     /**
      * Assemble two bytes into single integer value.
      *
      * @param data to be assembled
      * @return assembled value
      */
     static int twoBytesToInt(byte[] data) {
         return ((data[0] & 0xFF) << 8) | (data[1] & 0xFF);
     }

     /**
      * Assemble two bytes into single integer value.
      *
      * @param data to be assembled
      * @param offset offset to the data to convert in the array
      * @return assembled value
      */
     static int twoBytesToInt(byte[] data, int offset) {
         return ((data[offset] & 0xFF) << 8) | (data[offset + 1] & 0xFF);
     }

     /**
      * Assemble three bytes into single integer value.
      *
      * @param data to be assembled
      * @return assembled value
      */
     static int threeBytesToInt(byte[] data) {
         return ((data[0] & 0xFF) << 16) | ((data[1] & 0xFF) << 8) | (data[2] & 0xFF);
     }

     static <T> List<T> sparseArrayToList(SparseArray<T> array) {
         ArrayList<T> list = new ArrayList<>();
         for (int i = 0; i < array.size(); ++i) {
             list.add(array.valueAt(i));
         }
         return list;
     }

     static <T> List<T> mergeToUnmodifiableList(List<T> a, List<T> b) {
         if (a.isEmpty() && b.isEmpty()) {
             return Collections.emptyList();
         }
         if (a.isEmpty()) {
             return Collections.unmodifiableList(b);
         }
         if (b.isEmpty()) {
             return Collections.unmodifiableList(a);
         }
         List<T> newList = new ArrayList<>();
         newList.addAll(a);
         newList.addAll(b);
         return Collections.unmodifiableList(newList);
     }

     /**
      * See if the new path is affecting the active path.
      *
      * @param activePath current active path
      * @param newPath new path
      * @return true if the new path changes the current active path
      */
     static boolean isAffectingActiveRoutingPath(int activePath, int newPath) {
         // The new path affects the current active path if the parent of the new path
         // is an ancestor of the active path.
         // (1.1.0.0, 2.0.0.0) -> true, new path alters the parent
         // (1.1.0.0, 1.2.0.0) -> true, new path is a sibling
         // (1.1.0.0, 1.2.1.0) -> false, new path is a descendant of a sibling
         // (1.0.0.0, 3.2.0.0) -> false, in a completely different path

         // Get the parent of the new path by clearing the least significant
         // non-zero nibble.
         for (int i = 0; i <= 12; i += 4) {
             int nibble = (newPath >> i) & 0xF;
             if (nibble != 0) {
                 int mask = 0xFFF0 << i;
                 newPath &= mask;
                 break;
             }
         }
         if (newPath == 0x0000) {
             return true;  // Top path always affects the active path
         }
         return isInActiveRoutingPath(activePath, newPath);
     }

     /**
      * See if the new path is in the active path.
      *
      * @param activePath current active path
      * @param newPath new path
      * @return true if the new path in the active routing path
      */
     static boolean isInActiveRoutingPath(int activePath, int newPath) {
         // Check each nibble of the currently active path and the new path till the position
         // where the active nibble is not zero. For (activePath, newPath),
         // (1.1.0.0, 1.0.0.0) -> true, new path is a parent
         // (1.2.1.0, 1.2.1.2) -> true, new path is a descendant
         // (1.1.0.0, 1.2.0.0) -> false, new path is a sibling
         // (1.0.0.0, 2.0.0.0) -> false, in a completely different path
         for (int i = 12; i >= 0; i -= 4) {
             int nibbleActive = (activePath >> i) & 0xF;
             if (nibbleActive == 0) {
                 break;
             }
             int nibbleNew = (newPath >> i) & 0xF;
             if (nibbleNew == 0) {
                 break;
             }
             if (nibbleActive != nibbleNew) {
                 return false;
             }
         }
         return true;
     }

     /**
      * Clone {@link HdmiDeviceInfo} with new power status.
      */
     static HdmiDeviceInfo cloneHdmiDeviceInfo(HdmiDeviceInfo info, int newPowerStatus) {
         return new HdmiDeviceInfo(info.getLogicalAddress(),
                 info.getPhysicalAddress(), info.getPortId(), info.getDeviceType(),
                 info.getVendorId(), info.getDisplayName(), newPowerStatus);
     }

     /**
      * Dump a {@link SparseArray} to the print writer.
      *
      * <p>The dump is formatted:
      * <pre>
      *     name:
      *        key = value
      *        key = value
      *        ...
      * </pre>
      */
     static <T> void dumpSparseArray(IndentingPrintWriter pw, String name,
             SparseArray<T> sparseArray) {
         printWithTrailingColon(pw, name);
         pw.increaseIndent();
         int size = sparseArray.size();
         for (int i = 0; i < size; i++) {
             int key = sparseArray.keyAt(i);
             T value = sparseArray.get(key);
             pw.printPair(Integer.toString(key), value);
             pw.println();
         }
         pw.decreaseIndent();
     }

     private static void printWithTrailingColon(IndentingPrintWriter pw, String name) {
         pw.println(name.endsWith(":") ? name : name.concat(":"));
     }

     /**
      * Dump a {@link Map} to the print writer.
      *
      * <p>The dump is formatted:
      * <pre>
      *     name:
      *        key = value
      *        key = value
      *        ...
      * </pre>
      */
     static <K, V> void dumpMap(IndentingPrintWriter pw, String name, Map<K, V> map) {
         printWithTrailingColon(pw, name);
         pw.increaseIndent();
         for (Map.Entry<K, V> entry: map.entrySet()) {
             pw.printPair(entry.getKey().toString(), entry.getValue());
             pw.println();
         }
         pw.decreaseIndent();
     }

     /**
      * Dump a {@link Map} to the print writer.
      *
      * <p>The dump is formatted:
      * <pre>
      *     name:
      *        value
      *        value
      *        ...
      * </pre>
      */
     static <T> void dumpIterable(IndentingPrintWriter pw, String name, Iterable<T> values) {
         printWithTrailingColon(pw, name);
         pw.increaseIndent();
         for (T value : values) {
             pw.println(value);
         }
         pw.decreaseIndent();
     }

     /**
      * Method to parse target physical address to the port number on the current device.
      *
      * <p>This check assumes target address is valid.
      *
      * @param targetPhysicalAddress is the physical address of the target device
      * @param myPhysicalAddress is the physical address of the current device
      * @return
      * If the target device is under the current device, return the port number of current device
      * that the target device is connected to. This also applies to the devices that are indirectly
      * connected to the current device.
      *
      * <p>If the target device has the same physical address as the current device, return
      * {@link #TARGET_SAME_PHYSICAL_ADDRESS}.
      *
      * <p>If the target device is not under the current device, return
      * {@link #TARGET_NOT_UNDER_LOCAL_DEVICE}.
      */
     public static int getLocalPortFromPhysicalAddress(
             int targetPhysicalAddress, int myPhysicalAddress) {
         if (myPhysicalAddress == targetPhysicalAddress) {
             return TARGET_SAME_PHYSICAL_ADDRESS;
         }

         int mask = 0xF000;
         int finalMask = 0xF000;
         int maskedAddress = myPhysicalAddress;

         while (maskedAddress != 0) {
             maskedAddress = myPhysicalAddress & mask;
             finalMask |= mask;
             mask >>= 4;
         }

         int portAddress = targetPhysicalAddress & finalMask;
         if ((portAddress & (finalMask << 4)) != myPhysicalAddress) {
             return TARGET_NOT_UNDER_LOCAL_DEVICE;
         }

         mask <<= 4;
         int port = portAddress & mask;
         while ((port >> 4) != 0) {
             port >>= 4;
         }
         return port;
     }

     public static class ShortAudioDescriptorXmlParser {
         // We don't use namespaces
         private static final String NS = null;

         // return a list of devices config
         public static List<DeviceConfig> parse(InputStream in)
                 throws XmlPullParserException, IOException {
             XmlPullParser parser = Xml.newPullParser();
             parser.setFeature(XmlPullParser.FEATURE_PROCESS_NAMESPACES, false);
             parser.setInput(in, null);
             parser.nextTag();
             return readDevices(parser);
         }

         private static void skip(XmlPullParser parser) throws XmlPullParserException, IOException {
             if (parser.getEventType() != XmlPullParser.START_TAG) {
                 throw new IllegalStateException();
             }
             int depth = 1;
             while (depth != 0) {
                 switch (parser.next()) {
                     case XmlPullParser.END_TAG:
                         depth--;
                         break;
                     case XmlPullParser.START_TAG:
                         depth++;
                         break;
                 }
             }
         }

         private static List<DeviceConfig> readDevices(XmlPullParser parser)
                 throws XmlPullParserException, IOException {
             List<DeviceConfig> devices = new ArrayList<>();

             parser.require(XmlPullParser.START_TAG, NS, "config");
             while (parser.next() != XmlPullParser.END_TAG) {
                 if (parser.getEventType() != XmlPullParser.START_TAG) {
                     continue;
                 }
                 String name = parser.getName();
                 // Starts by looking for the device tag
                 if (name.equals("device")) {
                     String deviceType = parser.getAttributeValue(null, "type");
                     DeviceConfig config = null;
                     if (deviceType != null) {
                         config = readDeviceConfig(parser, deviceType);
                     }
                     if (config != null) {
                         devices.add(config);
                     }
                 } else {
                     skip(parser);
                 }
             }
             return devices;
         }

         // Processes device tags in the config.
         @Nullable
         private static DeviceConfig readDeviceConfig(XmlPullParser parser, String deviceType)
                 throws XmlPullParserException, IOException {
             List<CodecSad> codecSads = new ArrayList<>();
             int format;
             byte[] descriptor;

             parser.require(XmlPullParser.START_TAG, NS, "device");
             while (parser.next() != XmlPullParser.END_TAG) {
                 if (parser.getEventType() != XmlPullParser.START_TAG) {
                     continue;
                 }
                 String tagName = parser.getName();

                 // Starts by looking for the supportedFormat tag
                 if (tagName.equals("supportedFormat")) {
                     String codecAttriValue = parser.getAttributeValue(null, "format");
                     String sadAttriValue = parser.getAttributeValue(null, "descriptor");
                     format = (codecAttriValue) == null
                             ? Constants.AUDIO_CODEC_NONE : formatNameToNum(codecAttriValue);
                     descriptor = readSad(sadAttriValue);
                     if (format != Constants.AUDIO_CODEC_NONE && descriptor != null) {
                         codecSads.add(new CodecSad(format, descriptor));
                     }
                     parser.nextTag();
                     parser.require(XmlPullParser.END_TAG, NS, "supportedFormat");
                 } else {
                     skip(parser);
                 }
             }
             if (codecSads.size() == 0) {
                 return null;
             }
             return new DeviceConfig(deviceType, codecSads);
         }

         // Processes sad attribute in the supportedFormat.
         @Nullable
         private static byte[] readSad(String sad) {
             if (sad == null || sad.length() == 0) {
                 return null;
             }
             byte[] sadBytes = HexDump.hexStringToByteArray(sad);
             if (sadBytes.length != 3) {
                 Slog.w(TAG, "SAD byte array length is not 3. Length = " + sadBytes.length);
                 return null;
             }
             return sadBytes;
         }

         @AudioCodec
         private static int formatNameToNum(String codecAttriValue) {
             switch (codecAttriValue) {
                 case "AUDIO_FORMAT_NONE":
                     return Constants.AUDIO_CODEC_NONE;
                 case "AUDIO_FORMAT_LPCM":
                     return Constants.AUDIO_CODEC_LPCM;
                 case "AUDIO_FORMAT_DD":
                     return Constants.AUDIO_CODEC_DD;
                 case "AUDIO_FORMAT_MPEG1":
                     return Constants.AUDIO_CODEC_MPEG1;
                 case "AUDIO_FORMAT_MP3":
                     return Constants.AUDIO_CODEC_MP3;
                 case "AUDIO_FORMAT_MPEG2":
                     return Constants.AUDIO_CODEC_MPEG2;
                 case "AUDIO_FORMAT_AAC":
                     return Constants.AUDIO_CODEC_AAC;
                 case "AUDIO_FORMAT_DTS":
                     return Constants.AUDIO_CODEC_DTS;
                 case "AUDIO_FORMAT_ATRAC":
                     return Constants.AUDIO_CODEC_ATRAC;
                 case "AUDIO_FORMAT_ONEBITAUDIO":
                     return Constants.AUDIO_CODEC_ONEBITAUDIO;
                 case "AUDIO_FORMAT_DDP":
                     return Constants.AUDIO_CODEC_DDP;
                 case "AUDIO_FORMAT_DTSHD":
                     return Constants.AUDIO_CODEC_DTSHD;
                 case "AUDIO_FORMAT_TRUEHD":
                     return Constants.AUDIO_CODEC_TRUEHD;
                 case "AUDIO_FORMAT_DST":
                     return Constants.AUDIO_CODEC_DST;
                 case "AUDIO_FORMAT_WMAPRO":
                     return Constants.AUDIO_CODEC_WMAPRO;
                 case "AUDIO_FORMAT_MAX":
                     return Constants.AUDIO_CODEC_MAX;
                 default:
                     return Constants.AUDIO_CODEC_NONE;
             }
         }
     }

     // Device configuration of its supported Codecs and their Short Audio Descriptors.
     public static class DeviceConfig {
         /** Name of the device. Should be {@link Constants.AudioDevice}. **/
         public final String name;
         /** List of a {@link CodecSad}. **/
         public final List<CodecSad> supportedCodecs;

         public DeviceConfig(String name, List<CodecSad> supportedCodecs) {
             this.name = name;
             this.supportedCodecs = supportedCodecs;
         }

         @Override
         public boolean equals(Object obj) {
             if (obj instanceof DeviceConfig) {
                 DeviceConfig that = (DeviceConfig) obj;
                 return that.name.equals(this.name)
                     && that.supportedCodecs.equals(this.supportedCodecs);
             }
             return false;
         }

         @Override
         public int hashCode() {
             return Objects.hash(
                 name,
                 supportedCodecs.hashCode());
         }
     }

     // Short Audio Descriptor of a specific Codec
     public static class CodecSad {
         /** Audio Codec. Should be {@link Constants.AudioCodec}. **/
         public final int audioCodec;
         /**
          * Three-byte Short Audio Descriptor. See HDMI Specification 1.4b CEC 13.15.3 and
          * ANSI-CTA-861-F-FINAL 7.5.2 Audio Data Block for more details.
          */
         public final byte[] sad;

         public CodecSad(int audioCodec, byte[] sad) {
             this.audioCodec = audioCodec;
             this.sad = sad;
         }

         public CodecSad(int audioCodec, String sad) {
             this.audioCodec = audioCodec;
             this.sad = HexDump.hexStringToByteArray(sad);
         }

         @Override
         public boolean equals(Object obj) {
             if (obj instanceof CodecSad) {
                 CodecSad that = (CodecSad) obj;
                 return that.audioCodec == this.audioCodec
                     && Arrays.equals(that.sad, this.sad);
             }
             return false;
         }

         @Override
         public int hashCode() {
             return Objects.hash(
                 audioCodec,
                 Arrays.hashCode(sad));
         }
     }
 }
	/*
	* Copyright (C) 2014 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 com.android.server.hdmi;

	import android.annotation.Nullable;
	import android.hardware.hdmi.HdmiDeviceInfo;
	import android.util.Slog;
	import android.util.SparseArray;
	import android.util.Xml;

	import com.android.internal.util.HexDump;
	import com.android.internal.util.IndentingPrintWriter;
	import com.android.server.hdmi.Constants.AudioCodec;

	import org.xmlpull.v1.XmlPullParser;
	import org.xmlpull.v1.XmlPullParserException;

	import java.io.IOException;
	import java.io.InputStream;
	import java.util.ArrayList;
	import java.util.Arrays;
	import java.util.Collections;
	import java.util.List;
	import java.util.Map;
	import java.util.Objects;

	/**
	* Various utilities to handle HDMI CEC messages.
	*/
	final class HdmiUtils {

	private static final String TAG = "HdmiUtils";

	private static final int[] ADDRESS_TO_TYPE = {
	HdmiDeviceInfo.DEVICE_TV, // ADDR_TV
	HdmiDeviceInfo.DEVICE_RECORDER, // ADDR_RECORDER_1
	HdmiDeviceInfo.DEVICE_RECORDER, // ADDR_RECORDER_2
	HdmiDeviceInfo.DEVICE_TUNER, // ADDR_TUNER_1
	HdmiDeviceInfo.DEVICE_PLAYBACK, // ADDR_PLAYBACK_1
	HdmiDeviceInfo.DEVICE_AUDIO_SYSTEM, // ADDR_AUDIO_SYSTEM
	HdmiDeviceInfo.DEVICE_TUNER, // ADDR_TUNER_2
	HdmiDeviceInfo.DEVICE_TUNER, // ADDR_TUNER_3
	HdmiDeviceInfo.DEVICE_PLAYBACK, // ADDR_PLAYBACK_2
	HdmiDeviceInfo.DEVICE_RECORDER, // ADDR_RECORDER_3
	HdmiDeviceInfo.DEVICE_TUNER, // ADDR_TUNER_4
	HdmiDeviceInfo.DEVICE_PLAYBACK, // ADDR_PLAYBACK_3
	HdmiDeviceInfo.DEVICE_RESERVED,
	HdmiDeviceInfo.DEVICE_RESERVED,
	HdmiDeviceInfo.DEVICE_TV, // ADDR_SPECIFIC_USE
	};

	private static final String[] DEFAULT_NAMES = {
	"TV",
	"Recorder_1",
	"Recorder_2",
	"Tuner_1",
	"Playback_1",
	"AudioSystem",
	"Tuner_2",
	"Tuner_3",
	"Playback_2",
	"Recorder_3",
	"Tuner_4",
	"Playback_3",
	"Reserved_1",
	"Reserved_2",
	"Secondary_TV",
	};

	/**
	* Return value of {@link #getLocalPortFromPhysicalAddress(int, int)}
	*/
	static final int TARGET_NOT_UNDER_LOCAL_DEVICE = -1;
	static final int TARGET_SAME_PHYSICAL_ADDRESS = 0;

	private HdmiUtils() { /* cannot be instantiated */ }

	/**
	* Check if the given logical address is valid. A logical address is valid
	* if it is one allocated for an actual device which allows communication
	* with other logical devices.
	*
	* @param address logical address
	* @return true if the given address is valid
	*/
	static boolean isValidAddress(int address) {
	return (Constants.ADDR_TV <= address && address <= Constants.ADDR_SPECIFIC_USE);
	}

	/**
	* Return the device type for the given logical address.
	*
	* @param address logical address
	* @return device type for the given logical address; DEVICE_INACTIVE
	* if the address is not valid.
	*/
	static int getTypeFromAddress(int address) {
	if (isValidAddress(address)) {
	return ADDRESS_TO_TYPE[address];
	}
	return HdmiDeviceInfo.DEVICE_INACTIVE;
	}

	/**
	* Return the default device name for a logical address. This is the name
	* by which the logical device is known to others until a name is
	* set explicitly using HdmiCecService.setOsdName.
	*
	* @param address logical address
	* @return default device name; empty string if the address is not valid
	*/
	static String getDefaultDeviceName(int address) {
	if (isValidAddress(address)) {
	return DEFAULT_NAMES[address];
	}
	return "";
	}

	/**
	* Verify if the given address is for the given device type. If not it will throw
	* {@link IllegalArgumentException}.
	*
	* @param logicalAddress the logical address to verify
	* @param deviceType the device type to check
	* @throws IllegalArgumentException
	*/
	static void verifyAddressType(int logicalAddress, int deviceType) {
	int actualDeviceType = getTypeFromAddress(logicalAddress);
	if (actualDeviceType != deviceType) {
	throw new IllegalArgumentException("Device type missmatch:[Expected:" + deviceType
	+ ", Actual:" + actualDeviceType);
	}
	}

	/**
	* Check if the given CEC message come from the given address.
	*
	* @param cmd the CEC message to check
	* @param expectedAddress the expected source address of the given message
	* @param tag the tag of caller module (for log message)
	* @return true if the CEC message comes from the given address
	*/
	static boolean checkCommandSource(HdmiCecMessage cmd, int expectedAddress, String tag) {
	int src = cmd.getSource();
	if (src != expectedAddress) {
	Slog.w(tag, "Invalid source [Expected:" + expectedAddress + ", Actual:" + src + "]");
	return false;
	}
	return true;
	}

	/**
	* Parse the parameter block of CEC message as [System Audio Status].
	*
	* @param cmd the CEC message to parse
	* @return true if the given parameter has [ON] value
	*/
	static boolean parseCommandParamSystemAudioStatus(HdmiCecMessage cmd) {
	return cmd.getParams()[0] == Constants.SYSTEM_AUDIO_STATUS_ON;
	}

	/**
	* Parse the <Report Audio Status> message and check if it is mute
	*
	* @param cmd the CEC message to parse
	* @return true if the given parameter has [MUTE]
	*/
	static boolean isAudioStatusMute(HdmiCecMessage cmd) {
	byte params[] = cmd.getParams();
	return (params[0] & 0x80) == 0x80;
	}

	/**
	* Parse the <Report Audio Status> message and extract the volume
	*
	* @param cmd the CEC message to parse
	* @return device's volume. Constants.UNKNOWN_VOLUME in case it is out of range
	*/
	static int getAudioStatusVolume(HdmiCecMessage cmd) {
	byte params[] = cmd.getParams();
	int volume = params[0] & 0x7F;
	if (volume < 0x00 \|\| 0x64 < volume) {
	volume = Constants.UNKNOWN_VOLUME;
	}
	return volume;
	}

	/**
	* Convert integer array to list of {@link Integer}.
	*
	* <p>The result is immutable.
	*
	* @param is integer array
	* @return {@link List} instance containing the elements in the given array
	*/
	static List<Integer> asImmutableList(final int[] is) {
	ArrayList<Integer> list = new ArrayList<>(is.length);
	for (int type : is) {
	list.add(type);
	}
	return Collections.unmodifiableList(list);
	}

	/**
	* Assemble two bytes into single integer value.
	*
	* @param data to be assembled
	* @return assembled value
	*/
	static int twoBytesToInt(byte[] data) {
	return ((data[0] & 0xFF) << 8) \| (data[1] & 0xFF);
	}

	/**
	* Assemble two bytes into single integer value.
	*
	* @param data to be assembled
	* @param offset offset to the data to convert in the array
	* @return assembled value
	*/
	static int twoBytesToInt(byte[] data, int offset) {
	return ((data[offset] & 0xFF) << 8) \| (data[offset + 1] & 0xFF);
	}

	/**
	* Assemble three bytes into single integer value.
	*
	* @param data to be assembled
	* @return assembled value
	*/
	static int threeBytesToInt(byte[] data) {
	return ((data[0] & 0xFF) << 16) \| ((data[1] & 0xFF) << 8) \| (data[2] & 0xFF);
	}

	static <T> List<T> sparseArrayToList(SparseArray<T> array) {
	ArrayList<T> list = new ArrayList<>();
	for (int i = 0; i < array.size(); ++i) {
	list.add(array.valueAt(i));
	}
	return list;
	}

	static <T> List<T> mergeToUnmodifiableList(List<T> a, List<T> b) {
	if (a.isEmpty() && b.isEmpty()) {
	return Collections.emptyList();
	}
	if (a.isEmpty()) {
	return Collections.unmodifiableList(b);
	}
	if (b.isEmpty()) {
	return Collections.unmodifiableList(a);
	}
	List<T> newList = new ArrayList<>();
	newList.addAll(a);
	newList.addAll(b);
	return Collections.unmodifiableList(newList);
	}

	/**
	* See if the new path is affecting the active path.
	*
	* @param activePath current active path
	* @param newPath new path
	* @return true if the new path changes the current active path
	*/
	static boolean isAffectingActiveRoutingPath(int activePath, int newPath) {
	// The new path affects the current active path if the parent of the new path
	// is an ancestor of the active path.
	// (1.1.0.0, 2.0.0.0) -> true, new path alters the parent
	// (1.1.0.0, 1.2.0.0) -> true, new path is a sibling
	// (1.1.0.0, 1.2.1.0) -> false, new path is a descendant of a sibling
	// (1.0.0.0, 3.2.0.0) -> false, in a completely different path

	// Get the parent of the new path by clearing the least significant
	// non-zero nibble.
	for (int i = 0; i <= 12; i += 4) {
	int nibble = (newPath >> i) & 0xF;
	if (nibble != 0) {
	int mask = 0xFFF0 << i;
	newPath &= mask;
	break;
	}
	}
	if (newPath == 0x0000) {
	return true; // Top path always affects the active path
	}
	return isInActiveRoutingPath(activePath, newPath);
	}

	/**
	* See if the new path is in the active path.
	*
	* @param activePath current active path
	* @param newPath new path
	* @return true if the new path in the active routing path
	*/
	static boolean isInActiveRoutingPath(int activePath, int newPath) {
	// Check each nibble of the currently active path and the new path till the position
	// where the active nibble is not zero. For (activePath, newPath),
	// (1.1.0.0, 1.0.0.0) -> true, new path is a parent
	// (1.2.1.0, 1.2.1.2) -> true, new path is a descendant
	// (1.1.0.0, 1.2.0.0) -> false, new path is a sibling
	// (1.0.0.0, 2.0.0.0) -> false, in a completely different path
	for (int i = 12; i >= 0; i -= 4) {
	int nibbleActive = (activePath >> i) & 0xF;
	if (nibbleActive == 0) {
	break;
	}
	int nibbleNew = (newPath >> i) & 0xF;
	if (nibbleNew == 0) {
	break;
	}
	if (nibbleActive != nibbleNew) {
	return false;
	}
	}
	return true;
	}

	/**
	* Clone {@link HdmiDeviceInfo} with new power status.
	*/
	static HdmiDeviceInfo cloneHdmiDeviceInfo(HdmiDeviceInfo info, int newPowerStatus) {
	return new HdmiDeviceInfo(info.getLogicalAddress(),
	info.getPhysicalAddress(), info.getPortId(), info.getDeviceType(),
	info.getVendorId(), info.getDisplayName(), newPowerStatus);
	}

	/**
	* Dump a {@link SparseArray} to the print writer.
	*
	* <p>The dump is formatted:
	* <pre>
	* name:
	* key = value
	* key = value
	* ...
	* </pre>
	*/
	static <T> void dumpSparseArray(IndentingPrintWriter pw, String name,
	SparseArray<T> sparseArray) {
	printWithTrailingColon(pw, name);
	pw.increaseIndent();
	int size = sparseArray.size();
	for (int i = 0; i < size; i++) {
	int key = sparseArray.keyAt(i);
	T value = sparseArray.get(key);
	pw.printPair(Integer.toString(key), value);
	pw.println();
	}
	pw.decreaseIndent();
	}

	private static void printWithTrailingColon(IndentingPrintWriter pw, String name) {
	pw.println(name.endsWith(":") ? name : name.concat(":"));
	}

	/**
	* Dump a {@link Map} to the print writer.
	*
	* <p>The dump is formatted:
	* <pre>
	* name:
	* key = value
	* key = value
	* ...
	* </pre>
	*/
	static <K, V> void dumpMap(IndentingPrintWriter pw, String name, Map<K, V> map) {
	printWithTrailingColon(pw, name);
	pw.increaseIndent();
	for (Map.Entry<K, V> entry: map.entrySet()) {
	pw.printPair(entry.getKey().toString(), entry.getValue());
	pw.println();
	}
	pw.decreaseIndent();
	}

	/**
	* Dump a {@link Map} to the print writer.
	*
	* <p>The dump is formatted:
	* <pre>
	* name:
	* value
	* value
	* ...
	* </pre>
	*/
	static <T> void dumpIterable(IndentingPrintWriter pw, String name, Iterable<T> values) {
	printWithTrailingColon(pw, name);
	pw.increaseIndent();
	for (T value : values) {
	pw.println(value);
	}
	pw.decreaseIndent();
	}

	/**
	* Method to parse target physical address to the port number on the current device.
	*
	* <p>This check assumes target address is valid.
	*
	* @param targetPhysicalAddress is the physical address of the target device
	* @param myPhysicalAddress is the physical address of the current device
	* @return
	* If the target device is under the current device, return the port number of current device
	* that the target device is connected to. This also applies to the devices that are indirectly
	* connected to the current device.
	*
	* <p>If the target device has the same physical address as the current device, return
	* {@link #TARGET_SAME_PHYSICAL_ADDRESS}.
	*
	* <p>If the target device is not under the current device, return
	* {@link #TARGET_NOT_UNDER_LOCAL_DEVICE}.
	*/
	public static int getLocalPortFromPhysicalAddress(
	int targetPhysicalAddress, int myPhysicalAddress) {
	if (myPhysicalAddress == targetPhysicalAddress) {
	return TARGET_SAME_PHYSICAL_ADDRESS;
	}

	int mask = 0xF000;
	int finalMask = 0xF000;
	int maskedAddress = myPhysicalAddress;

	while (maskedAddress != 0) {
	maskedAddress = myPhysicalAddress & mask;
	finalMask \|= mask;
	mask >>= 4;
	}

	int portAddress = targetPhysicalAddress & finalMask;
	if ((portAddress & (finalMask << 4)) != myPhysicalAddress) {
	return TARGET_NOT_UNDER_LOCAL_DEVICE;
	}

	mask <<= 4;
	int port = portAddress & mask;
	while ((port >> 4) != 0) {
	port >>= 4;
	}
	return port;
	}

	public static class ShortAudioDescriptorXmlParser {
	// We don't use namespaces
	private static final String NS = null;

	// return a list of devices config
	public static List<DeviceConfig> parse(InputStream in)
	throws XmlPullParserException, IOException {
	XmlPullParser parser = Xml.newPullParser();
	parser.setFeature(XmlPullParser.FEATURE_PROCESS_NAMESPACES, false);
	parser.setInput(in, null);
	parser.nextTag();
	return readDevices(parser);
	}

	private static void skip(XmlPullParser parser) throws XmlPullParserException, IOException {
	if (parser.getEventType() != XmlPullParser.START_TAG) {
	throw new IllegalStateException();
	}
	int depth = 1;
	while (depth != 0) {
	switch (parser.next()) {
	case XmlPullParser.END_TAG:
	depth--;
	break;
	case XmlPullParser.START_TAG:
	depth++;
	break;
	}
	}
	}

	private static List<DeviceConfig> readDevices(XmlPullParser parser)
	throws XmlPullParserException, IOException {
	List<DeviceConfig> devices = new ArrayList<>();

	parser.require(XmlPullParser.START_TAG, NS, "config");
	while (parser.next() != XmlPullParser.END_TAG) {
	if (parser.getEventType() != XmlPullParser.START_TAG) {
	continue;
	}
	String name = parser.getName();
	// Starts by looking for the device tag
	if (name.equals("device")) {
	String deviceType = parser.getAttributeValue(null, "type");
	DeviceConfig config = null;
	if (deviceType != null) {
	config = readDeviceConfig(parser, deviceType);
	}
	if (config != null) {
	devices.add(config);
	}
	} else {
	skip(parser);
	}
	}
	return devices;
	}

	// Processes device tags in the config.
	@Nullable
	private static DeviceConfig readDeviceConfig(XmlPullParser parser, String deviceType)
	throws XmlPullParserException, IOException {
	List<CodecSad> codecSads = new ArrayList<>();
	int format;
	byte[] descriptor;

	parser.require(XmlPullParser.START_TAG, NS, "device");
	while (parser.next() != XmlPullParser.END_TAG) {
	if (parser.getEventType() != XmlPullParser.START_TAG) {
	continue;
	}
	String tagName = parser.getName();

	// Starts by looking for the supportedFormat tag
	if (tagName.equals("supportedFormat")) {
	String codecAttriValue = parser.getAttributeValue(null, "format");
	String sadAttriValue = parser.getAttributeValue(null, "descriptor");
	format = (codecAttriValue) == null
	? Constants.AUDIO_CODEC_NONE : formatNameToNum(codecAttriValue);
	descriptor = readSad(sadAttriValue);
	if (format != Constants.AUDIO_CODEC_NONE && descriptor != null) {
	codecSads.add(new CodecSad(format, descriptor));
	}
	parser.nextTag();
	parser.require(XmlPullParser.END_TAG, NS, "supportedFormat");
	} else {
	skip(parser);
	}
	}
	if (codecSads.size() == 0) {
	return null;
	}
	return new DeviceConfig(deviceType, codecSads);
	}

	// Processes sad attribute in the supportedFormat.
	@Nullable
	private static byte[] readSad(String sad) {
	if (sad == null \|\| sad.length() == 0) {
	return null;
	}
	byte[] sadBytes = HexDump.hexStringToByteArray(sad);
	if (sadBytes.length != 3) {
	Slog.w(TAG, "SAD byte array length is not 3. Length = " + sadBytes.length);
	return null;
	}
	return sadBytes;
	}

	@AudioCodec
	private static int formatNameToNum(String codecAttriValue) {
	switch (codecAttriValue) {
	case "AUDIO_FORMAT_NONE":
	return Constants.AUDIO_CODEC_NONE;
	case "AUDIO_FORMAT_LPCM":
	return Constants.AUDIO_CODEC_LPCM;
	case "AUDIO_FORMAT_DD":
	return Constants.AUDIO_CODEC_DD;
	case "AUDIO_FORMAT_MPEG1":
	return Constants.AUDIO_CODEC_MPEG1;
	case "AUDIO_FORMAT_MP3":
	return Constants.AUDIO_CODEC_MP3;
	case "AUDIO_FORMAT_MPEG2":
	return Constants.AUDIO_CODEC_MPEG2;
	case "AUDIO_FORMAT_AAC":
	return Constants.AUDIO_CODEC_AAC;
	case "AUDIO_FORMAT_DTS":
	return Constants.AUDIO_CODEC_DTS;
	case "AUDIO_FORMAT_ATRAC":
	return Constants.AUDIO_CODEC_ATRAC;
	case "AUDIO_FORMAT_ONEBITAUDIO":
	return Constants.AUDIO_CODEC_ONEBITAUDIO;
	case "AUDIO_FORMAT_DDP":
	return Constants.AUDIO_CODEC_DDP;
	case "AUDIO_FORMAT_DTSHD":
	return Constants.AUDIO_CODEC_DTSHD;
	case "AUDIO_FORMAT_TRUEHD":
	return Constants.AUDIO_CODEC_TRUEHD;
	case "AUDIO_FORMAT_DST":
	return Constants.AUDIO_CODEC_DST;
	case "AUDIO_FORMAT_WMAPRO":
	return Constants.AUDIO_CODEC_WMAPRO;
	case "AUDIO_FORMAT_MAX":
	return Constants.AUDIO_CODEC_MAX;
	default:
	return Constants.AUDIO_CODEC_NONE;
	}
	}
	}

	// Device configuration of its supported Codecs and their Short Audio Descriptors.
	public static class DeviceConfig {
	/ Name of the device. Should be {@link Constants.AudioDevice}. /
	public final String name;
	/ List of a {@link CodecSad}. /
	public final List<CodecSad> supportedCodecs;

	public DeviceConfig(String name, List<CodecSad> supportedCodecs) {
	this.name = name;
	this.supportedCodecs = supportedCodecs;
	}

	@Override
	public boolean equals(Object obj) {
	if (obj instanceof DeviceConfig) {
	DeviceConfig that = (DeviceConfig) obj;
	return that.name.equals(this.name)
	&& that.supportedCodecs.equals(this.supportedCodecs);
	}
	return false;
	}

	@Override
	public int hashCode() {
	return Objects.hash(
	name,
	supportedCodecs.hashCode());
	}
	}

	// Short Audio Descriptor of a specific Codec
	public static class CodecSad {
	/ Audio Codec. Should be {@link Constants.AudioCodec}. /
	public final int audioCodec;
	/**
	* Three-byte Short Audio Descriptor. See HDMI Specification 1.4b CEC 13.15.3 and
	* ANSI-CTA-861-F-FINAL 7.5.2 Audio Data Block for more details.
	*/
	public final byte[] sad;

	public CodecSad(int audioCodec, byte[] sad) {
	this.audioCodec = audioCodec;
	this.sad = sad;
	}

	public CodecSad(int audioCodec, String sad) {
	this.audioCodec = audioCodec;
	this.sad = HexDump.hexStringToByteArray(sad);
	}

	@Override
	public boolean equals(Object obj) {
	if (obj instanceof CodecSad) {
	CodecSad that = (CodecSad) obj;
	return that.audioCodec == this.audioCodec
	&& Arrays.equals(that.sad, this.sad);
	}
	return false;
	}

	@Override
	public int hashCode() {
	return Objects.hash(
	audioCodec,
	Arrays.hashCode(sad));
	}
	}
	}