android/location/GpsClock.java - platform/prebuilts/fullsdk/sources/android-30 - 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 android.location;

 import android.annotation.NonNull;
 import android.annotation.SystemApi;
 import android.os.Parcel;
 import android.os.Parcelable;

 /**
  * A class containing a GPS clock timestamp.
  * It represents a measurement of the GPS receiver's clock.
  *
  * @deprecated use {@link GnssClock} instead.
  *
  * @hide
  */
 @Deprecated
 @SystemApi
 public class GpsClock implements Parcelable {

     // The following enumerations must be in sync with the values declared in gps.h

     /**
      * The type of the time stored is not available or it is unknown.
      */
     public static final byte TYPE_UNKNOWN = 0;

     /**
      * The source of the time value reported by this class is the 'Local Hardware Clock'.
      */
     public static final byte TYPE_LOCAL_HW_TIME = 1;

     /**
      * The source of the time value reported by this class is the 'GPS time' derived from
      * satellites (epoch = Jan 6, 1980).
      */
     public static final byte TYPE_GPS_TIME = 2;

     private static final short HAS_NO_FLAGS = 0;
     private static final short HAS_LEAP_SECOND = (1<<0);
     private static final short HAS_TIME_UNCERTAINTY = (1<<1);
     private static final short HAS_FULL_BIAS = (1<<2);
     private static final short HAS_BIAS = (1<<3);
     private static final short HAS_BIAS_UNCERTAINTY = (1<<4);
     private static final short HAS_DRIFT = (1<<5);
     private static final short HAS_DRIFT_UNCERTAINTY = (1<<6);

     // End enumerations in sync with gps.h

     private short mFlags;
     private short mLeapSecond;
     private byte mType;
     private long mTimeInNs;
     private double mTimeUncertaintyInNs;
     private long mFullBiasInNs;
     private double mBiasInNs;
     private double mBiasUncertaintyInNs;
     private double mDriftInNsPerSec;
     private double mDriftUncertaintyInNsPerSec;

     GpsClock() {
         initialize();
     }

     /**
      * Sets all contents to the values stored in the provided object.
      */
     public void set(GpsClock clock) {
         mFlags = clock.mFlags;
         mLeapSecond = clock.mLeapSecond;
         mType = clock.mType;
         mTimeInNs = clock.mTimeInNs;
         mTimeUncertaintyInNs = clock.mTimeUncertaintyInNs;
         mFullBiasInNs = clock.mFullBiasInNs;
         mBiasInNs = clock.mBiasInNs;
         mBiasUncertaintyInNs = clock.mBiasUncertaintyInNs;
         mDriftInNsPerSec = clock.mDriftInNsPerSec;
         mDriftUncertaintyInNsPerSec = clock.mDriftUncertaintyInNsPerSec;
     }

     /**
      * Resets all the contents to its original state.
      */
     public void reset() {
         initialize();
     }

     /**
      * Gets the type of time reported by {@link #getTimeInNs()}.
      */
     public byte getType() {
         return mType;
     }

     /**
      * Sets the type of time reported.
      */
     public void setType(byte value) {
         mType = value;
     }

     /**
      * Gets a string representation of the 'type'.
      * For internal and logging use only.
      */
     private String getTypeString() {
         switch (mType) {
             case TYPE_UNKNOWN:
                 return "Unknown";
             case TYPE_GPS_TIME:
                 return "GpsTime";
             case TYPE_LOCAL_HW_TIME:
                 return "LocalHwClock";
             default:
                 return "<Invalid:" + mType + ">";
         }
     }

     /**
      * Returns true if {@link #getLeapSecond()} is available, false otherwise.
      */
     public boolean hasLeapSecond() {
         return isFlagSet(HAS_LEAP_SECOND);
     }

     /**
      * Gets the leap second associated with the clock's time.
      * The sign of the value is defined by the following equation:
      *      utc_time_ns = time_ns + (full_bias_ns + bias_ns) - leap_second * 1,000,000,000
      *
      * The value is only available if {@link #hasLeapSecond()} is true.
      */
     public short getLeapSecond() {
         return mLeapSecond;
     }

     /**
      * Sets the leap second associated with the clock's time.
      */
     public void setLeapSecond(short leapSecond) {
         setFlag(HAS_LEAP_SECOND);
         mLeapSecond = leapSecond;
     }

     /**
      * Resets the leap second associated with the clock's time.
      */
     public void resetLeapSecond() {
         resetFlag(HAS_LEAP_SECOND);
         mLeapSecond = Short.MIN_VALUE;
     }

     /**
      * Gets the GPS receiver internal clock value in nanoseconds.
      * This can be either the 'local hardware clock' value ({@link #TYPE_LOCAL_HW_TIME}), or the
      * current GPS time derived inside GPS receiver ({@link #TYPE_GPS_TIME}).
      * {@link #getType()} defines the time reported.
      *
      * For 'local hardware clock' this value is expected to be monotonically increasing during the
      * reporting session. The real GPS time can be derived by compensating
      * {@link #getFullBiasInNs()} (when it is available) from this value.
      *
      * For 'GPS time' this value is expected to be the best estimation of current GPS time that GPS
      * receiver can achieve. {@link #getTimeUncertaintyInNs()} should be available when GPS time is
      * specified.
      *
      * Sub-nanosecond accuracy can be provided by means of {@link #getBiasInNs()}.
      * The reported time includes {@link #getTimeUncertaintyInNs()}.
      */
     public long getTimeInNs() {
         return mTimeInNs;
     }

     /**
      * Sets the GPS receiver internal clock in nanoseconds.
      */
     public void setTimeInNs(long timeInNs) {
         mTimeInNs = timeInNs;
     }

     /**
      * Returns true if {@link #getTimeUncertaintyInNs()} is available, false otherwise.
      */
     public boolean hasTimeUncertaintyInNs() {
         return isFlagSet(HAS_TIME_UNCERTAINTY);
     }

     /**
      * Gets the clock's time Uncertainty (1-Sigma) in nanoseconds.
      * The uncertainty is represented as an absolute (single sided) value.
      *
      * The value is only available if {@link #hasTimeUncertaintyInNs()} is true.
      */
     public double getTimeUncertaintyInNs() {
         return mTimeUncertaintyInNs;
     }

     /**
      * Sets the clock's Time Uncertainty (1-Sigma) in nanoseconds.
      */
     public void setTimeUncertaintyInNs(double timeUncertaintyInNs) {
         setFlag(HAS_TIME_UNCERTAINTY);
         mTimeUncertaintyInNs = timeUncertaintyInNs;
     }

     /**
      * Resets the clock's Time Uncertainty (1-Sigma) in nanoseconds.
      */
     public void resetTimeUncertaintyInNs() {
         resetFlag(HAS_TIME_UNCERTAINTY);
         mTimeUncertaintyInNs = Double.NaN;
     }

     /**
      * Returns true if {@link @getFullBiasInNs()} is available, false otherwise.
      */
     public boolean hasFullBiasInNs() {
         return isFlagSet(HAS_FULL_BIAS);
     }

     /**
      * Gets the difference between hardware clock ({@link #getTimeInNs()}) inside GPS receiver and
      * the true GPS time since 0000Z, January 6, 1980, in nanoseconds.
      *
      * This value is available if {@link #TYPE_LOCAL_HW_TIME} is set, and GPS receiver has solved
      * the clock for GPS time.
      * {@link #getBiasUncertaintyInNs()} should be used for quality check.
      *
      * The sign of the value is defined by the following equation:
      *      true time (GPS time) = time_ns + (full_bias_ns + bias_ns)
      *
      * The reported full bias includes {@link #getBiasUncertaintyInNs()}.
      * The value is onl available if {@link #hasFullBiasInNs()} is true.
      */
     public long getFullBiasInNs() {
         return mFullBiasInNs;
     }

     /**
      * Sets the full bias in nanoseconds.
      */
     public void setFullBiasInNs(long value) {
         setFlag(HAS_FULL_BIAS);
         mFullBiasInNs = value;
     }

     /**
      * Resets the full bias in nanoseconds.
      */
     public void resetFullBiasInNs() {
         resetFlag(HAS_FULL_BIAS);
         mFullBiasInNs = Long.MIN_VALUE;
     }

     /**
      * Returns true if {@link #getBiasInNs()} is available, false otherwise.
      */
     public boolean hasBiasInNs() {
         return isFlagSet(HAS_BIAS);
     }

     /**
      * Gets the clock's sub-nanosecond bias.
      * The reported bias includes {@link #getBiasUncertaintyInNs()}.
      *
      * The value is only available if {@link #hasBiasInNs()} is true.
      */
     public double getBiasInNs() {
         return mBiasInNs;
     }

     /**
      * Sets the sub-nanosecond bias.
      */
     public void setBiasInNs(double biasInNs) {
         setFlag(HAS_BIAS);
         mBiasInNs = biasInNs;
     }

     /**
      * Resets the clock's Bias in nanoseconds.
      */
     public void resetBiasInNs() {
         resetFlag(HAS_BIAS);
         mBiasInNs = Double.NaN;
     }

     /**
      * Returns true if {@link #getBiasUncertaintyInNs()} is available, false otherwise.
      */
     public boolean hasBiasUncertaintyInNs() {
         return isFlagSet(HAS_BIAS_UNCERTAINTY);
     }

     /**
      * Gets the clock's Bias Uncertainty (1-Sigma) in nanoseconds.
      *
      * The value is only available if {@link #hasBiasUncertaintyInNs()} is true.
      */
     public double getBiasUncertaintyInNs() {
         return mBiasUncertaintyInNs;
     }

     /**
      * Sets the clock's Bias Uncertainty (1-Sigma) in nanoseconds.
      */
     public void setBiasUncertaintyInNs(double biasUncertaintyInNs) {
         setFlag(HAS_BIAS_UNCERTAINTY);
         mBiasUncertaintyInNs = biasUncertaintyInNs;
     }

     /**
      * Resets the clock's Bias Uncertainty (1-Sigma) in nanoseconds.
      */
     public void resetBiasUncertaintyInNs() {
         resetFlag(HAS_BIAS_UNCERTAINTY);
         mBiasUncertaintyInNs = Double.NaN;
     }

     /**
      * Returns true if {@link #getDriftInNsPerSec()} is available, false otherwise.
      */
     public boolean hasDriftInNsPerSec() {
         return isFlagSet(HAS_DRIFT);
     }

     /**
      * Gets the clock's Drift in nanoseconds per second.
      * A positive value indicates that the frequency is higher than the nominal frequency.
      * The reported drift includes {@link #getDriftUncertaintyInNsPerSec()}.
      *
      * The value is only available if {@link #hasDriftInNsPerSec()} is true.
      */
     public double getDriftInNsPerSec() {
         return mDriftInNsPerSec;
     }

     /**
      * Sets the clock's Drift in nanoseconds per second.
      */
     public void setDriftInNsPerSec(double driftInNsPerSec) {
         setFlag(HAS_DRIFT);
         mDriftInNsPerSec = driftInNsPerSec;
     }

     /**
      * Resets the clock's Drift in nanoseconds per second.
      */
     public void resetDriftInNsPerSec() {
         resetFlag(HAS_DRIFT);
         mDriftInNsPerSec = Double.NaN;
     }

     /**
      * Returns true if {@link #getDriftUncertaintyInNsPerSec()} is available, false otherwise.
      */
     public boolean hasDriftUncertaintyInNsPerSec() {
         return isFlagSet(HAS_DRIFT_UNCERTAINTY);
     }

     /**
      * Gets the clock's Drift Uncertainty (1-Sigma) in nanoseconds per second.
      *
      * The value is only available if {@link #hasDriftUncertaintyInNsPerSec()} is true.
      */
     public double getDriftUncertaintyInNsPerSec() {
         return mDriftUncertaintyInNsPerSec;
     }

     /**
      * Sets the clock's Drift Uncertainty (1-Sigma) in nanoseconds per second.
      */
     public void setDriftUncertaintyInNsPerSec(double driftUncertaintyInNsPerSec) {
         setFlag(HAS_DRIFT_UNCERTAINTY);
         mDriftUncertaintyInNsPerSec = driftUncertaintyInNsPerSec;
     }

     /**
      * Resets the clock's Drift Uncertainty (1-Sigma) in nanoseconds per second.
      */
     public void resetDriftUncertaintyInNsPerSec() {
         resetFlag(HAS_DRIFT_UNCERTAINTY);
         mDriftUncertaintyInNsPerSec = Double.NaN;
     }

     public static final @android.annotation.NonNull Creator<GpsClock> CREATOR = new Creator<GpsClock>() {
         @Override
         public GpsClock createFromParcel(Parcel parcel) {
             GpsClock gpsClock = new GpsClock();

             gpsClock.mFlags = (short) parcel.readInt();
             gpsClock.mLeapSecond = (short) parcel.readInt();
             gpsClock.mType = parcel.readByte();
             gpsClock.mTimeInNs = parcel.readLong();
             gpsClock.mTimeUncertaintyInNs = parcel.readDouble();
             gpsClock.mFullBiasInNs = parcel.readLong();
             gpsClock.mBiasInNs = parcel.readDouble();
             gpsClock.mBiasUncertaintyInNs = parcel.readDouble();
             gpsClock.mDriftInNsPerSec = parcel.readDouble();
             gpsClock.mDriftUncertaintyInNsPerSec = parcel.readDouble();

             return gpsClock;
         }

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

     public void writeToParcel(Parcel parcel, int flags) {
         parcel.writeInt(mFlags);
         parcel.writeInt(mLeapSecond);
         parcel.writeByte(mType);
         parcel.writeLong(mTimeInNs);
         parcel.writeDouble(mTimeUncertaintyInNs);
         parcel.writeLong(mFullBiasInNs);
         parcel.writeDouble(mBiasInNs);
         parcel.writeDouble(mBiasUncertaintyInNs);
         parcel.writeDouble(mDriftInNsPerSec);
         parcel.writeDouble(mDriftUncertaintyInNsPerSec);
     }

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

     @NonNull
     @Override
     public String toString() {
         final String format = "   %-15s = %s\n";
         final String formatWithUncertainty = "   %-15s = %-25s   %-26s = %s\n";
         StringBuilder builder = new StringBuilder("GpsClock:\n");

         builder.append(String.format(format, "Type", getTypeString()));

         builder.append(String.format(format, "LeapSecond", hasLeapSecond() ? mLeapSecond : null));

         builder.append(String.format(
                 formatWithUncertainty,
                 "TimeInNs",
                 mTimeInNs,
                 "TimeUncertaintyInNs",
                 hasTimeUncertaintyInNs() ? mTimeUncertaintyInNs : null));

         builder.append(String.format(
                 format,
                 "FullBiasInNs",
                 hasFullBiasInNs() ? mFullBiasInNs : null));

         builder.append(String.format(
                 formatWithUncertainty,
                 "BiasInNs",
                 hasBiasInNs() ? mBiasInNs : null,
                 "BiasUncertaintyInNs",
                 hasBiasUncertaintyInNs() ? mBiasUncertaintyInNs : null));

         builder.append(String.format(
                 formatWithUncertainty,
                 "DriftInNsPerSec",
                 hasDriftInNsPerSec() ? mDriftInNsPerSec : null,
                 "DriftUncertaintyInNsPerSec",
                 hasDriftUncertaintyInNsPerSec() ? mDriftUncertaintyInNsPerSec : null));

         return builder.toString();
     }

     private void initialize() {
         mFlags = HAS_NO_FLAGS;
         resetLeapSecond();
         setType(TYPE_UNKNOWN);
         setTimeInNs(Long.MIN_VALUE);
         resetTimeUncertaintyInNs();
         resetFullBiasInNs();
         resetBiasInNs();
         resetBiasUncertaintyInNs();
         resetDriftInNsPerSec();
         resetDriftUncertaintyInNsPerSec();
     }

     private void setFlag(short flag) {
         mFlags |= flag;
     }

     private void resetFlag(short flag) {
         mFlags &= ~flag;
     }

     private boolean isFlagSet(short flag) {
         return (mFlags & flag) == flag;
     }
 }
	/*
	* 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 android.location;

	import android.annotation.NonNull;
	import android.annotation.SystemApi;
	import android.os.Parcel;
	import android.os.Parcelable;

	/**
	* A class containing a GPS clock timestamp.
	* It represents a measurement of the GPS receiver's clock.
	*
	* @deprecated use {@link GnssClock} instead.
	*
	* @hide
	*/
	@Deprecated
	@SystemApi
	public class GpsClock implements Parcelable {

	// The following enumerations must be in sync with the values declared in gps.h

	/**
	* The type of the time stored is not available or it is unknown.
	*/
	public static final byte TYPE_UNKNOWN = 0;

	/**
	* The source of the time value reported by this class is the 'Local Hardware Clock'.
	*/
	public static final byte TYPE_LOCAL_HW_TIME = 1;

	/**
	* The source of the time value reported by this class is the 'GPS time' derived from
	* satellites (epoch = Jan 6, 1980).
	*/
	public static final byte TYPE_GPS_TIME = 2;

	private static final short HAS_NO_FLAGS = 0;
	private static final short HAS_LEAP_SECOND = (1<<0);
	private static final short HAS_TIME_UNCERTAINTY = (1<<1);
	private static final short HAS_FULL_BIAS = (1<<2);
	private static final short HAS_BIAS = (1<<3);
	private static final short HAS_BIAS_UNCERTAINTY = (1<<4);
	private static final short HAS_DRIFT = (1<<5);
	private static final short HAS_DRIFT_UNCERTAINTY = (1<<6);

	// End enumerations in sync with gps.h

	private short mFlags;
	private short mLeapSecond;
	private byte mType;
	private long mTimeInNs;
	private double mTimeUncertaintyInNs;
	private long mFullBiasInNs;
	private double mBiasInNs;
	private double mBiasUncertaintyInNs;
	private double mDriftInNsPerSec;
	private double mDriftUncertaintyInNsPerSec;

	GpsClock() {
	initialize();
	}

	/**
	* Sets all contents to the values stored in the provided object.
	*/
	public void set(GpsClock clock) {
	mFlags = clock.mFlags;
	mLeapSecond = clock.mLeapSecond;
	mType = clock.mType;
	mTimeInNs = clock.mTimeInNs;
	mTimeUncertaintyInNs = clock.mTimeUncertaintyInNs;
	mFullBiasInNs = clock.mFullBiasInNs;
	mBiasInNs = clock.mBiasInNs;
	mBiasUncertaintyInNs = clock.mBiasUncertaintyInNs;
	mDriftInNsPerSec = clock.mDriftInNsPerSec;
	mDriftUncertaintyInNsPerSec = clock.mDriftUncertaintyInNsPerSec;
	}

	/**
	* Resets all the contents to its original state.
	*/
	public void reset() {
	initialize();
	}

	/**
	* Gets the type of time reported by {@link #getTimeInNs()}.
	*/
	public byte getType() {
	return mType;
	}

	/**
	* Sets the type of time reported.
	*/
	public void setType(byte value) {
	mType = value;
	}

	/**
	* Gets a string representation of the 'type'.
	* For internal and logging use only.
	*/
	private String getTypeString() {
	switch (mType) {
	case TYPE_UNKNOWN:
	return "Unknown";
	case TYPE_GPS_TIME:
	return "GpsTime";
	case TYPE_LOCAL_HW_TIME:
	return "LocalHwClock";
	default:
	return "<Invalid:" + mType + ">";
	}
	}

	/**
	* Returns true if {@link #getLeapSecond()} is available, false otherwise.
	*/
	public boolean hasLeapSecond() {
	return isFlagSet(HAS_LEAP_SECOND);
	}

	/**
	* Gets the leap second associated with the clock's time.
	* The sign of the value is defined by the following equation:
	* utc_time_ns = time_ns + (full_bias_ns + bias_ns) - leap_second * 1,000,000,000
	*
	* The value is only available if {@link #hasLeapSecond()} is true.
	*/
	public short getLeapSecond() {
	return mLeapSecond;
	}

	/**
	* Sets the leap second associated with the clock's time.
	*/
	public void setLeapSecond(short leapSecond) {
	setFlag(HAS_LEAP_SECOND);
	mLeapSecond = leapSecond;
	}

	/**
	* Resets the leap second associated with the clock's time.
	*/
	public void resetLeapSecond() {
	resetFlag(HAS_LEAP_SECOND);
	mLeapSecond = Short.MIN_VALUE;
	}

	/**
	* Gets the GPS receiver internal clock value in nanoseconds.
	* This can be either the 'local hardware clock' value ({@link #TYPE_LOCAL_HW_TIME}), or the
	* current GPS time derived inside GPS receiver ({@link #TYPE_GPS_TIME}).
	* {@link #getType()} defines the time reported.
	*
	* For 'local hardware clock' this value is expected to be monotonically increasing during the
	* reporting session. The real GPS time can be derived by compensating
	* {@link #getFullBiasInNs()} (when it is available) from this value.
	*
	* For 'GPS time' this value is expected to be the best estimation of current GPS time that GPS
	* receiver can achieve. {@link #getTimeUncertaintyInNs()} should be available when GPS time is
	* specified.
	*
	* Sub-nanosecond accuracy can be provided by means of {@link #getBiasInNs()}.
	* The reported time includes {@link #getTimeUncertaintyInNs()}.
	*/
	public long getTimeInNs() {
	return mTimeInNs;
	}

	/**
	* Sets the GPS receiver internal clock in nanoseconds.
	*/
	public void setTimeInNs(long timeInNs) {
	mTimeInNs = timeInNs;
	}

	/**
	* Returns true if {@link #getTimeUncertaintyInNs()} is available, false otherwise.
	*/
	public boolean hasTimeUncertaintyInNs() {
	return isFlagSet(HAS_TIME_UNCERTAINTY);
	}

	/**
	* Gets the clock's time Uncertainty (1-Sigma) in nanoseconds.
	* The uncertainty is represented as an absolute (single sided) value.
	*
	* The value is only available if {@link #hasTimeUncertaintyInNs()} is true.
	*/
	public double getTimeUncertaintyInNs() {
	return mTimeUncertaintyInNs;
	}

	/**
	* Sets the clock's Time Uncertainty (1-Sigma) in nanoseconds.
	*/
	public void setTimeUncertaintyInNs(double timeUncertaintyInNs) {
	setFlag(HAS_TIME_UNCERTAINTY);
	mTimeUncertaintyInNs = timeUncertaintyInNs;
	}

	/**
	* Resets the clock's Time Uncertainty (1-Sigma) in nanoseconds.
	*/
	public void resetTimeUncertaintyInNs() {
	resetFlag(HAS_TIME_UNCERTAINTY);
	mTimeUncertaintyInNs = Double.NaN;
	}

	/**
	* Returns true if {@link @getFullBiasInNs()} is available, false otherwise.
	*/
	public boolean hasFullBiasInNs() {
	return isFlagSet(HAS_FULL_BIAS);
	}

	/**
	* Gets the difference between hardware clock ({@link #getTimeInNs()}) inside GPS receiver and
	* the true GPS time since 0000Z, January 6, 1980, in nanoseconds.
	*
	* This value is available if {@link #TYPE_LOCAL_HW_TIME} is set, and GPS receiver has solved
	* the clock for GPS time.
	* {@link #getBiasUncertaintyInNs()} should be used for quality check.
	*
	* The sign of the value is defined by the following equation:
	* true time (GPS time) = time_ns + (full_bias_ns + bias_ns)
	*
	* The reported full bias includes {@link #getBiasUncertaintyInNs()}.
	* The value is onl available if {@link #hasFullBiasInNs()} is true.
	*/
	public long getFullBiasInNs() {
	return mFullBiasInNs;
	}

	/**
	* Sets the full bias in nanoseconds.
	*/
	public void setFullBiasInNs(long value) {
	setFlag(HAS_FULL_BIAS);
	mFullBiasInNs = value;
	}

	/**
	* Resets the full bias in nanoseconds.
	*/
	public void resetFullBiasInNs() {
	resetFlag(HAS_FULL_BIAS);
	mFullBiasInNs = Long.MIN_VALUE;
	}

	/**
	* Returns true if {@link #getBiasInNs()} is available, false otherwise.
	*/
	public boolean hasBiasInNs() {
	return isFlagSet(HAS_BIAS);
	}

	/**
	* Gets the clock's sub-nanosecond bias.
	* The reported bias includes {@link #getBiasUncertaintyInNs()}.
	*
	* The value is only available if {@link #hasBiasInNs()} is true.
	*/
	public double getBiasInNs() {
	return mBiasInNs;
	}

	/**
	* Sets the sub-nanosecond bias.
	*/
	public void setBiasInNs(double biasInNs) {
	setFlag(HAS_BIAS);
	mBiasInNs = biasInNs;
	}

	/**
	* Resets the clock's Bias in nanoseconds.
	*/
	public void resetBiasInNs() {
	resetFlag(HAS_BIAS);
	mBiasInNs = Double.NaN;
	}

	/**
	* Returns true if {@link #getBiasUncertaintyInNs()} is available, false otherwise.
	*/
	public boolean hasBiasUncertaintyInNs() {
	return isFlagSet(HAS_BIAS_UNCERTAINTY);
	}

	/**
	* Gets the clock's Bias Uncertainty (1-Sigma) in nanoseconds.
	*
	* The value is only available if {@link #hasBiasUncertaintyInNs()} is true.
	*/
	public double getBiasUncertaintyInNs() {
	return mBiasUncertaintyInNs;
	}

	/**
	* Sets the clock's Bias Uncertainty (1-Sigma) in nanoseconds.
	*/
	public void setBiasUncertaintyInNs(double biasUncertaintyInNs) {
	setFlag(HAS_BIAS_UNCERTAINTY);
	mBiasUncertaintyInNs = biasUncertaintyInNs;
	}

	/**
	* Resets the clock's Bias Uncertainty (1-Sigma) in nanoseconds.
	*/
	public void resetBiasUncertaintyInNs() {
	resetFlag(HAS_BIAS_UNCERTAINTY);
	mBiasUncertaintyInNs = Double.NaN;
	}

	/**
	* Returns true if {@link #getDriftInNsPerSec()} is available, false otherwise.
	*/
	public boolean hasDriftInNsPerSec() {
	return isFlagSet(HAS_DRIFT);
	}

	/**
	* Gets the clock's Drift in nanoseconds per second.
	* A positive value indicates that the frequency is higher than the nominal frequency.
	* The reported drift includes {@link #getDriftUncertaintyInNsPerSec()}.
	*
	* The value is only available if {@link #hasDriftInNsPerSec()} is true.
	*/
	public double getDriftInNsPerSec() {
	return mDriftInNsPerSec;
	}

	/**
	* Sets the clock's Drift in nanoseconds per second.
	*/
	public void setDriftInNsPerSec(double driftInNsPerSec) {
	setFlag(HAS_DRIFT);
	mDriftInNsPerSec = driftInNsPerSec;
	}

	/**
	* Resets the clock's Drift in nanoseconds per second.
	*/
	public void resetDriftInNsPerSec() {
	resetFlag(HAS_DRIFT);
	mDriftInNsPerSec = Double.NaN;
	}

	/**
	* Returns true if {@link #getDriftUncertaintyInNsPerSec()} is available, false otherwise.
	*/
	public boolean hasDriftUncertaintyInNsPerSec() {
	return isFlagSet(HAS_DRIFT_UNCERTAINTY);
	}

	/**
	* Gets the clock's Drift Uncertainty (1-Sigma) in nanoseconds per second.
	*
	* The value is only available if {@link #hasDriftUncertaintyInNsPerSec()} is true.
	*/
	public double getDriftUncertaintyInNsPerSec() {
	return mDriftUncertaintyInNsPerSec;
	}

	/**
	* Sets the clock's Drift Uncertainty (1-Sigma) in nanoseconds per second.
	*/
	public void setDriftUncertaintyInNsPerSec(double driftUncertaintyInNsPerSec) {
	setFlag(HAS_DRIFT_UNCERTAINTY);
	mDriftUncertaintyInNsPerSec = driftUncertaintyInNsPerSec;
	}

	/**
	* Resets the clock's Drift Uncertainty (1-Sigma) in nanoseconds per second.
	*/
	public void resetDriftUncertaintyInNsPerSec() {
	resetFlag(HAS_DRIFT_UNCERTAINTY);
	mDriftUncertaintyInNsPerSec = Double.NaN;
	}

	public static final @android.annotation.NonNull Creator<GpsClock> CREATOR = new Creator<GpsClock>() {
	@Override
	public GpsClock createFromParcel(Parcel parcel) {
	GpsClock gpsClock = new GpsClock();

	gpsClock.mFlags = (short) parcel.readInt();
	gpsClock.mLeapSecond = (short) parcel.readInt();
	gpsClock.mType = parcel.readByte();
	gpsClock.mTimeInNs = parcel.readLong();
	gpsClock.mTimeUncertaintyInNs = parcel.readDouble();
	gpsClock.mFullBiasInNs = parcel.readLong();
	gpsClock.mBiasInNs = parcel.readDouble();
	gpsClock.mBiasUncertaintyInNs = parcel.readDouble();
	gpsClock.mDriftInNsPerSec = parcel.readDouble();
	gpsClock.mDriftUncertaintyInNsPerSec = parcel.readDouble();

	return gpsClock;
	}

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

	public void writeToParcel(Parcel parcel, int flags) {
	parcel.writeInt(mFlags);
	parcel.writeInt(mLeapSecond);
	parcel.writeByte(mType);
	parcel.writeLong(mTimeInNs);
	parcel.writeDouble(mTimeUncertaintyInNs);
	parcel.writeLong(mFullBiasInNs);
	parcel.writeDouble(mBiasInNs);
	parcel.writeDouble(mBiasUncertaintyInNs);
	parcel.writeDouble(mDriftInNsPerSec);
	parcel.writeDouble(mDriftUncertaintyInNsPerSec);
	}

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

	@NonNull
	@Override
	public String toString() {
	final String format = " %-15s = %s\n";
	final String formatWithUncertainty = " %-15s = %-25s %-26s = %s\n";
	StringBuilder builder = new StringBuilder("GpsClock:\n");

	builder.append(String.format(format, "Type", getTypeString()));

	builder.append(String.format(format, "LeapSecond", hasLeapSecond() ? mLeapSecond : null));

	builder.append(String.format(
	formatWithUncertainty,
	"TimeInNs",
	mTimeInNs,
	"TimeUncertaintyInNs",
	hasTimeUncertaintyInNs() ? mTimeUncertaintyInNs : null));

	builder.append(String.format(
	format,
	"FullBiasInNs",
	hasFullBiasInNs() ? mFullBiasInNs : null));

	builder.append(String.format(
	formatWithUncertainty,
	"BiasInNs",
	hasBiasInNs() ? mBiasInNs : null,
	"BiasUncertaintyInNs",
	hasBiasUncertaintyInNs() ? mBiasUncertaintyInNs : null));

	builder.append(String.format(
	formatWithUncertainty,
	"DriftInNsPerSec",
	hasDriftInNsPerSec() ? mDriftInNsPerSec : null,
	"DriftUncertaintyInNsPerSec",
	hasDriftUncertaintyInNsPerSec() ? mDriftUncertaintyInNsPerSec : null));

	return builder.toString();
	}

	private void initialize() {
	mFlags = HAS_NO_FLAGS;
	resetLeapSecond();
	setType(TYPE_UNKNOWN);
	setTimeInNs(Long.MIN_VALUE);
	resetTimeUncertaintyInNs();
	resetFullBiasInNs();
	resetBiasInNs();
	resetBiasUncertaintyInNs();
	resetDriftInNsPerSec();
	resetDriftUncertaintyInNsPerSec();
	}

	private void setFlag(short flag) {
	mFlags \|= flag;
	}

	private void resetFlag(short flag) {
	mFlags &= ~flag;
	}

	private boolean isFlagSet(short flag) {
	return (mFlags & flag) == flag;
	}
	}