location/java/android/location/Location.java - platform/frameworks/base - Git at Google

 /*
  * Copyright (C) 2007 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.os.Bundle;
 import android.os.Parcel;
 import android.os.Parcelable;
 import android.util.Printer;

 import java.text.DecimalFormat;
 import java.util.StringTokenizer;

 /**
  * A class representing a geographic location sensed at a particular
  * time (a "fix").  A location consists of a latitude and longitude, a
  * UTC timestamp. and optionally information on altitude, speed, and
  * bearing.
  *
  * <p> Information specific to a particular provider or class of
  * providers may be communicated to the application using getExtras,
  * which returns a Bundle of key/value pairs.  Each provider will only
  * provide those entries for which information is available.
  */
 public class Location implements Parcelable {
     /**
      * Constant used to specify formatting of a latitude or longitude
      * in the form "[+-]DDD.DDDDD where D indicates degrees.
      */
     public static final int FORMAT_DEGREES = 0;

     /**
      * Constant used to specify formatting of a latitude or longitude
      * in the form "[+-]DDD:MM.MMMMM" where D indicates degrees and
      * M indicates minutes of arc (1 minute = 1/60th of a degree).
      */
     public static final int FORMAT_MINUTES = 1;

     /**
      * Constant used to specify formatting of a latitude or longitude
      * in the form "DDD:MM:SS.SSSSS" where D indicates degrees, M
      * indicates minutes of arc, and S indicates seconds of arc (1
      * minute = 1/60th of a degree, 1 second = 1/3600th of a degree).
      */
     public static final int FORMAT_SECONDS = 2;

     private String mProvider;
     private long mTime = 0;
     private double mLatitude = 0.0;
     private double mLongitude = 0.0;
     private boolean mHasAltitude = false;
     private double mAltitude = 0.0f;
     private boolean mHasSpeed = false;
     private float mSpeed = 0.0f;
     private boolean mHasBearing = false;
     private float mBearing = 0.0f;
     private boolean mHasAccuracy = false;
     private float mAccuracy = 0.0f;
     private Bundle mExtras = null;

     // Cache the inputs and outputs of computeDistanceAndBearing
     // so calls to distanceTo() and bearingTo() can share work
     private double mLat1 = 0.0;
     private double mLon1 = 0.0;
     private double mLat2 = 0.0;
     private double mLon2 = 0.0;
     private float mDistance = 0.0f;
     private float mInitialBearing = 0.0f;
     // Scratchpad
     private float[] mResults = new float[2];

     public void dump(Printer pw, String prefix) {
         pw.println(prefix + "mProvider=" + mProvider + " mTime=" + mTime);
         pw.println(prefix + "mLatitude=" + mLatitude + " mLongitude=" + mLongitude);
         pw.println(prefix + "mHasAltitude=" + mHasAltitude + " mAltitude=" + mAltitude);
         pw.println(prefix + "mHasSpeed=" + mHasSpeed + " mSpeed=" + mSpeed);
         pw.println(prefix + "mHasBearing=" + mHasBearing + " mBearing=" + mBearing);
         pw.println(prefix + "mHasAccuracy=" + mHasAccuracy + " mAccuracy=" + mAccuracy);
         pw.println(prefix + "mExtras=" + mExtras);
     }

     /**
      * Constructs a new Location.  By default, time, latitude,
      * longitude, and numSatellites are 0; hasAltitude, hasSpeed, and
      * hasBearing are false; and there is no extra information.
      *
      * @param provider the name of the location provider that generated this
      * location fix.
      */
     public Location(String provider) {
         mProvider = provider;
     }

     /**
      * Constructs a new Location object that is a copy of the given
      * location.
      */
     public Location(Location l) {
         set(l);
     }

     /**
      * Sets the contents of the location to the values from the given location.
      */
     public void set(Location l) {
         mProvider = l.mProvider;
         mTime = l.mTime;
         mLatitude = l.mLatitude;
         mLongitude = l.mLongitude;
         mHasAltitude = l.mHasAltitude;
         mAltitude = l.mAltitude;
         mHasSpeed = l.mHasSpeed;
         mSpeed = l.mSpeed;
         mHasBearing = l.mHasBearing;
         mBearing = l.mBearing;
         mHasAccuracy = l.mHasAccuracy;
         mAccuracy = l.mAccuracy;
         mExtras = (l.mExtras == null) ? null : new Bundle(l.mExtras);
     }

     /**
      * Clears the contents of the location.
      */
     public void reset() {
         mProvider = null;
         mTime = 0;
         mLatitude = 0;
         mLongitude = 0;
         mHasAltitude = false;
         mAltitude = 0;
         mHasSpeed = false;
         mSpeed = 0;
         mHasBearing = false;
         mBearing = 0;
         mHasAccuracy = false;
         mAccuracy = 0;
         mExtras = null;
     }

     /**
      * Converts a coordinate to a String representation. The outputType
      * may be one of FORMAT_DEGREES, FORMAT_MINUTES, or FORMAT_SECONDS.
      * The coordinate must be a valid double between -180.0 and 180.0.
      *
      * @throws IllegalArgumentException if coordinate is less than
      * -180.0, greater than 180.0, or is not a number.
      * @throws IllegalArgumentException if outputType is not one of
      * FORMAT_DEGREES, FORMAT_MINUTES, or FORMAT_SECONDS.
      */
     public static String convert(double coordinate, int outputType) {
         if (coordinate < -180.0 || coordinate > 180.0 ||
             Double.isNaN(coordinate)) {
             throw new IllegalArgumentException("coordinate=" + coordinate);
         }
         if ((outputType != FORMAT_DEGREES) &&
             (outputType != FORMAT_MINUTES) &&
             (outputType != FORMAT_SECONDS)) {
             throw new IllegalArgumentException("outputType=" + outputType);
         }

         StringBuilder sb = new StringBuilder();

         // Handle negative values
         if (coordinate < 0) {
             sb.append('-');
             coordinate = -coordinate;
         }

         DecimalFormat df = new DecimalFormat("###.#####");
         if (outputType == FORMAT_MINUTES || outputType == FORMAT_SECONDS) {
             int degrees = (int) Math.floor(coordinate);
             sb.append(degrees);
             sb.append(':');
             coordinate -= degrees;
             coordinate *= 60.0;
             if (outputType == FORMAT_SECONDS) {
                 int minutes = (int) Math.floor(coordinate);
                 sb.append(minutes);
                 sb.append(':');
                 coordinate -= minutes;
                 coordinate *= 60.0;
             }
         }
         sb.append(df.format(coordinate));
         return sb.toString();
     }

     /**
      * Converts a String in one of the formats described by
      * FORMAT_DEGREES, FORMAT_MINUTES, or FORMAT_SECONDS into a
      * double.
      *
      * @throws NullPointerException if coordinate is null
      * @throws IllegalArgumentException if the coordinate is not
      * in one of the valid formats.
      */
     public static double convert(String coordinate) {
         // IllegalArgumentException if bad syntax
         if (coordinate == null) {
             throw new NullPointerException("coordinate");
         }

         boolean negative = false;
         if (coordinate.charAt(0) == '-') {
             coordinate = coordinate.substring(1);
             negative = true;
         }

         StringTokenizer st = new StringTokenizer(coordinate, ":");
         int tokens = st.countTokens();
         if (tokens < 1) {
             throw new IllegalArgumentException("coordinate=" + coordinate);
         }
         try {
             String degrees = st.nextToken();
             double val;
             if (tokens == 1) {
                 val = Double.parseDouble(degrees);
                 return negative ? -val : val;
             }

             String minutes = st.nextToken();
             int deg = Integer.parseInt(degrees);
             double min;
             double sec = 0.0;

             if (st.hasMoreTokens()) {
                 min = Integer.parseInt(minutes);
                 String seconds = st.nextToken();
                 sec = Double.parseDouble(seconds);
             } else {
                 min = Double.parseDouble(minutes);
             }

             boolean isNegative180 = negative && (deg == 180) &&
                 (min == 0) && (sec == 0);

             // deg must be in [0, 179] except for the case of -180 degrees
             if ((deg < 0.0) || (deg > 179 && !isNegative180)) {
                 throw new IllegalArgumentException("coordinate=" + coordinate);
             }
             if (min < 0 || min > 59) {
                 throw new IllegalArgumentException("coordinate=" +
                         coordinate);
             }
             if (sec < 0 || sec > 59) {
                 throw new IllegalArgumentException("coordinate=" +
                         coordinate);
             }

             val = deg*3600.0 + min*60.0 + sec;
             val /= 3600.0;
             return negative ? -val : val;
         } catch (NumberFormatException nfe) {
             throw new IllegalArgumentException("coordinate=" + coordinate);
         }
     }

     private static void computeDistanceAndBearing(double lat1, double lon1,
         double lat2, double lon2, float[] results) {
         // Based on http://www.ngs.noaa.gov/PUBS_LIB/inverse.pdf
         // using the "Inverse Formula" (section 4)

         int MAXITERS = 20;
         // Convert lat/long to radians
         lat1 *= Math.PI / 180.0;
         lat2 *= Math.PI / 180.0;
         lon1 *= Math.PI / 180.0;
         lon2 *= Math.PI / 180.0;

         double a = 6378137.0; // WGS84 major axis
         double b = 6356752.3142; // WGS84 semi-major axis
         double f = (a - b) / a;
         double aSqMinusBSqOverBSq = (a * a - b * b) / (b * b);

         double L = lon2 - lon1;
         double A = 0.0;
         double U1 = Math.atan((1.0 - f) * Math.tan(lat1));
         double U2 = Math.atan((1.0 - f) * Math.tan(lat2));

         double cosU1 = Math.cos(U1);
         double cosU2 = Math.cos(U2);
         double sinU1 = Math.sin(U1);
         double sinU2 = Math.sin(U2);
         double cosU1cosU2 = cosU1 * cosU2;
         double sinU1sinU2 = sinU1 * sinU2;

         double sigma = 0.0;
         double deltaSigma = 0.0;
         double cosSqAlpha = 0.0;
         double cos2SM = 0.0;
         double cosSigma = 0.0;
         double sinSigma = 0.0;
         double cosLambda = 0.0;
         double sinLambda = 0.0;

         double lambda = L; // initial guess
         for (int iter = 0; iter < MAXITERS; iter++) {
             double lambdaOrig = lambda;
             cosLambda = Math.cos(lambda);
             sinLambda = Math.sin(lambda);
             double t1 = cosU2 * sinLambda;
             double t2 = cosU1 * sinU2 - sinU1 * cosU2 * cosLambda;
             double sinSqSigma = t1 * t1 + t2 * t2; // (14)
             sinSigma = Math.sqrt(sinSqSigma);
             cosSigma = sinU1sinU2 + cosU1cosU2 * cosLambda; // (15)
             sigma = Math.atan2(sinSigma, cosSigma); // (16)
             double sinAlpha = (sinSigma == 0) ? 0.0 :
                 cosU1cosU2 * sinLambda / sinSigma; // (17)
             cosSqAlpha = 1.0 - sinAlpha * sinAlpha;
             cos2SM = (cosSqAlpha == 0) ? 0.0 :
                 cosSigma - 2.0 * sinU1sinU2 / cosSqAlpha; // (18)

             double uSquared = cosSqAlpha * aSqMinusBSqOverBSq; // defn
             A = 1 + (uSquared / 16384.0) * // (3)
                 (4096.0 + uSquared *
                  (-768 + uSquared * (320.0 - 175.0 * uSquared)));
             double B = (uSquared / 1024.0) * // (4)
                 (256.0 + uSquared *
                  (-128.0 + uSquared * (74.0 - 47.0 * uSquared)));
             double C = (f / 16.0) *
                 cosSqAlpha *
                 (4.0 + f * (4.0 - 3.0 * cosSqAlpha)); // (10)
             double cos2SMSq = cos2SM * cos2SM;
             deltaSigma = B * sinSigma * // (6)
                 (cos2SM + (B / 4.0) *
                  (cosSigma * (-1.0 + 2.0 * cos2SMSq) -
                   (B / 6.0) * cos2SM *
                   (-3.0 + 4.0 * sinSigma * sinSigma) *
                   (-3.0 + 4.0 * cos2SMSq)));

             lambda = L +
                 (1.0 - C) * f * sinAlpha *
                 (sigma + C * sinSigma *
                  (cos2SM + C * cosSigma *
                   (-1.0 + 2.0 * cos2SM * cos2SM))); // (11)

             double delta = (lambda - lambdaOrig) / lambda;
             if (Math.abs(delta) < 1.0e-12) {
                 break;
             }
         }

         float distance = (float) (b * A * (sigma - deltaSigma));
         results[0] = distance;
         if (results.length > 1) {
             float initialBearing = (float) Math.atan2(cosU2 * sinLambda,
                 cosU1 * sinU2 - sinU1 * cosU2 * cosLambda);
             initialBearing *= 180.0 / Math.PI;
             results[1] = initialBearing;
             if (results.length > 2) {
                 float finalBearing = (float) Math.atan2(cosU1 * sinLambda,
                     -sinU1 * cosU2 + cosU1 * sinU2 * cosLambda);
                 finalBearing *= 180.0 / Math.PI;
                 results[2] = finalBearing;
             }
         }
     }

     /**
      * Computes the approximate distance in meters between two
      * locations, and optionally the initial and final bearings of the
      * shortest path between them.  Distance and bearing are defined using the
      * WGS84 ellipsoid.
      *
      * <p> The computed distance is stored in results[0].  If results has length
      * 2 or greater, the initial bearing is stored in results[1]. If results has
      * length 3 or greater, the final bearing is stored in results[2].
      *
      * @param startLatitude the starting latitude
      * @param startLongitude the starting longitude
      * @param endLatitude the ending latitude
      * @param endLongitude the ending longitude
      * @param results an array of floats to hold the results
      *
      * @throws IllegalArgumentException if results is null or has length < 1
      */
     public static void distanceBetween(double startLatitude, double startLongitude,
         double endLatitude, double endLongitude, float[] results) {
         if (results == null || results.length < 1) {
             throw new IllegalArgumentException("results is null or has length < 1");
         }
         computeDistanceAndBearing(startLatitude, startLongitude,
             endLatitude, endLongitude, results);
     }

     /**
      * Returns the approximate distance in meters between this
      * location and the given location.  Distance is defined using
      * the WGS84 ellipsoid.
      *
      * @param dest the destination location
      * @return the approximate distance in meters
      */
     public float distanceTo(Location dest) {
         // See if we already have the result
         synchronized (mResults) {
             if (mLatitude != mLat1 || mLongitude != mLon1 ||
                 dest.mLatitude != mLat2 || dest.mLongitude != mLon2) {
                 computeDistanceAndBearing(mLatitude, mLongitude,
                     dest.mLatitude, dest.mLongitude, mResults);
                 mLat1 = mLatitude;
                 mLon1 = mLongitude;
                 mLat2 = dest.mLatitude;
                 mLon2 = dest.mLongitude;
                 mDistance = mResults[0];
                 mInitialBearing = mResults[1];
             }
             return mDistance;
         }
     }

     /**
      * Returns the approximate initial bearing in degrees East of true
      * North when traveling along the shortest path between this
      * location and the given location.  The shortest path is defined
      * using the WGS84 ellipsoid.  Locations that are (nearly)
      * antipodal may produce meaningless results.
      *
      * @param dest the destination location
      * @return the initial bearing in degrees
      */
     public float bearingTo(Location dest) {
         synchronized (mResults) {
             // See if we already have the result
             if (mLatitude != mLat1 || mLongitude != mLon1 ||
                             dest.mLatitude != mLat2 || dest.mLongitude != mLon2) {
                 computeDistanceAndBearing(mLatitude, mLongitude,
                     dest.mLatitude, dest.mLongitude, mResults);
                 mLat1 = mLatitude;
                 mLon1 = mLongitude;
                 mLat2 = dest.mLatitude;
                 mLon2 = dest.mLongitude;
                 mDistance = mResults[0];
                 mInitialBearing = mResults[1];
             }
             return mInitialBearing;
         }
     }

     /**
      * Returns the name of the provider that generated this fix,
      * or null if it is not associated with a provider.
      */
     public String getProvider() {
         return mProvider;
     }

     /**
      * Sets the name of the provider that generated this fix.
      */
     public void setProvider(String provider) {
         mProvider = provider;
     }

     /**
      * Returns the UTC time of this fix, in milliseconds since January 1,
      * 1970.
      */
     public long getTime() {
         return mTime;
     }

     /**
      * Sets the UTC time of this fix, in milliseconds since January 1,
      * 1970.
      */
     public void setTime(long time) {
         mTime = time;
     }

     /**
      * Returns the latitude of this fix.
      */
     public double getLatitude() {
         return mLatitude;
     }

     /**
      * Sets the latitude of this fix.
      */
     public void setLatitude(double latitude) {
         mLatitude = latitude;
     }

     /**
      * Returns the longitude of this fix.
      */
     public double getLongitude() {
         return mLongitude;
     }

     /**
      * Sets the longitude of this fix.
      */
     public void setLongitude(double longitude) {
         mLongitude = longitude;
     }

     /**
      * Returns true if this fix contains altitude information, false
      * otherwise.
      */
     public boolean hasAltitude() {
         return mHasAltitude;
     }

     /**
      * Returns the altitude of this fix.  If {@link #hasAltitude} is false,
      * 0.0f is returned.
      */
     public double getAltitude() {
         return mAltitude;
     }

     /**
      * Sets the altitude of this fix.  Following this call,
      * hasAltitude() will return true.
      */
     public void setAltitude(double altitude) {
         mAltitude = altitude;
         mHasAltitude = true;
     }

     /**
      * Clears the altitude of this fix.  Following this call,
      * hasAltitude() will return false.
      */
     public void removeAltitude() {
         mAltitude = 0.0f;
         mHasAltitude = false;
     }

     /**
      * Returns true if this fix contains speed information, false
      * otherwise.  The default implementation returns false.
      */
     public boolean hasSpeed() {
         return mHasSpeed;
     }

     /**
      * Returns the speed of the device over ground in meters/second.
      * If hasSpeed() is false, 0.0f is returned.
      */
     public float getSpeed() {
         return mSpeed;
     }

     /**
      * Sets the speed of this fix, in meters/second.  Following this
      * call, hasSpeed() will return true.
      */
     public void setSpeed(float speed) {
         mSpeed = speed;
         mHasSpeed = true;
     }

     /**
      * Clears the speed of this fix.  Following this call, hasSpeed()
      * will return false.
      */
     public void removeSpeed() {
         mSpeed = 0.0f;
         mHasSpeed = false;
     }

     /**
      * Returns true if the provider is able to report bearing information,
      * false otherwise.  The default implementation returns false.
      */
     public boolean hasBearing() {
         return mHasBearing;
     }

     /**
      * Returns the direction of travel in degrees East of true
      * North. If hasBearing() is false, 0.0 is returned.
      */
     public float getBearing() {
         return mBearing;
     }

     /**
      * Sets the bearing of this fix.  Following this call, hasBearing()
      * will return true.
      */
     public void setBearing(float bearing) {
         while (bearing < 0.0f) {
             bearing += 360.0f;
         }
         while (bearing >= 360.0f) {
             bearing -= 360.0f;
         }
         mBearing = bearing;
         mHasBearing = true;
     }

     /**
      * Clears the bearing of this fix.  Following this call, hasBearing()
      * will return false.
      */
     public void removeBearing() {
         mBearing = 0.0f;
         mHasBearing = false;
     }

     /**
      * Returns true if the provider is able to report accuracy information,
      * false otherwise.  The default implementation returns false.
      */
     public boolean hasAccuracy() {
         return mHasAccuracy;
     }

     /**
      * Returns the accuracy of the fix in meters. If hasAccuracy() is false,
      * 0.0 is returned.
      */
     public float getAccuracy() {
         return mAccuracy;
     }

     /**
      * Sets the accuracy of this fix.  Following this call, hasAccuracy()
      * will return true.
      */
     public void setAccuracy(float accuracy) {
         mAccuracy = accuracy;
         mHasAccuracy = true;
     }

     /**
      * Clears the accuracy of this fix.  Following this call, hasAccuracy()
      * will return false.
      */
     public void removeAccuracy() {
         mAccuracy = 0.0f;
         mHasAccuracy = false;
     }

     /**
      * Returns additional provider-specific information about the
      * location fix as a Bundle.  The keys and values are determined
      * by the provider.  If no additional information is available,
      * null is returned.
      *
      * <p> A number of common key/value pairs are listed
      * below. Providers that use any of the keys on this list must
      * provide the corresponding value as described below.
      *
      * <ul>
      * <li> satellites - the number of satellites used to derive the fix
      * </ul>
      */
     public Bundle getExtras() {
         return mExtras;
     }

     /**
      * Sets the extra information associated with this fix to the
      * given Bundle.
      */
     public void setExtras(Bundle extras) {
         mExtras = (extras == null) ? null : new Bundle(extras);
     }

     @Override public String toString() {
         return "Location[mProvider=" + mProvider +
             ",mTime=" + mTime +
             ",mLatitude=" + mLatitude +
             ",mLongitude=" + mLongitude +
             ",mHasAltitude=" + mHasAltitude +
             ",mAltitude=" + mAltitude +
             ",mHasSpeed=" + mHasSpeed +
             ",mSpeed=" + mSpeed +
             ",mHasBearing=" + mHasBearing +
             ",mBearing=" + mBearing +
             ",mHasAccuracy=" + mHasAccuracy +
             ",mAccuracy=" + mAccuracy +
             ",mExtras=" + mExtras + "]";
     }

     public static final Parcelable.Creator<Location> CREATOR =
         new Parcelable.Creator<Location>() {
         public Location createFromParcel(Parcel in) {
             String provider = in.readString();
             Location l = new Location(provider);
             l.mTime = in.readLong();
             l.mLatitude = in.readDouble();
             l.mLongitude = in.readDouble();
             l.mHasAltitude = in.readInt() != 0;
             l.mAltitude = in.readDouble();
             l.mHasSpeed = in.readInt() != 0;
             l.mSpeed = in.readFloat();
             l.mHasBearing = in.readInt() != 0;
             l.mBearing = in.readFloat();
             l.mHasAccuracy = in.readInt() != 0;
             l.mAccuracy = in.readFloat();
             l.mExtras = in.readBundle();
             return l;
         }

         public Location[] newArray(int size) {
             return new Location[size];
         }
     };

     public int describeContents() {
         return 0;
     }

     public void writeToParcel(Parcel parcel, int flags) {
         parcel.writeString(mProvider);
         parcel.writeLong(mTime);
         parcel.writeDouble(mLatitude);
         parcel.writeDouble(mLongitude);
         parcel.writeInt(mHasAltitude ? 1 : 0);
         parcel.writeDouble(mAltitude);
         parcel.writeInt(mHasSpeed ? 1 : 0);
         parcel.writeFloat(mSpeed);
         parcel.writeInt(mHasBearing ? 1 : 0);
         parcel.writeFloat(mBearing);
         parcel.writeInt(mHasAccuracy ? 1 : 0);
         parcel.writeFloat(mAccuracy);
         parcel.writeBundle(mExtras);
    }
 }
	/*
	* Copyright (C) 2007 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.os.Bundle;
	import android.os.Parcel;
	import android.os.Parcelable;
	import android.util.Printer;

	import java.text.DecimalFormat;
	import java.util.StringTokenizer;

	/**
	* A class representing a geographic location sensed at a particular
	* time (a "fix"). A location consists of a latitude and longitude, a
	* UTC timestamp. and optionally information on altitude, speed, and
	* bearing.
	*
	* <p> Information specific to a particular provider or class of
	* providers may be communicated to the application using getExtras,
	* which returns a Bundle of key/value pairs. Each provider will only
	* provide those entries for which information is available.
	*/
	public class Location implements Parcelable {
	/**
	* Constant used to specify formatting of a latitude or longitude
	* in the form "[+-]DDD.DDDDD where D indicates degrees.
	*/
	public static final int FORMAT_DEGREES = 0;

	/**
	* Constant used to specify formatting of a latitude or longitude
	* in the form "[+-]DDD:MM.MMMMM" where D indicates degrees and
	* M indicates minutes of arc (1 minute = 1/60th of a degree).
	*/
	public static final int FORMAT_MINUTES = 1;

	/**
	* Constant used to specify formatting of a latitude or longitude
	* in the form "DDD:MM:SS.SSSSS" where D indicates degrees, M
	* indicates minutes of arc, and S indicates seconds of arc (1
	* minute = 1/60th of a degree, 1 second = 1/3600th of a degree).
	*/
	public static final int FORMAT_SECONDS = 2;

	private String mProvider;
	private long mTime = 0;
	private double mLatitude = 0.0;
	private double mLongitude = 0.0;
	private boolean mHasAltitude = false;
	private double mAltitude = 0.0f;
	private boolean mHasSpeed = false;
	private float mSpeed = 0.0f;
	private boolean mHasBearing = false;
	private float mBearing = 0.0f;
	private boolean mHasAccuracy = false;
	private float mAccuracy = 0.0f;
	private Bundle mExtras = null;

	// Cache the inputs and outputs of computeDistanceAndBearing
	// so calls to distanceTo() and bearingTo() can share work
	private double mLat1 = 0.0;
	private double mLon1 = 0.0;
	private double mLat2 = 0.0;
	private double mLon2 = 0.0;
	private float mDistance = 0.0f;
	private float mInitialBearing = 0.0f;
	// Scratchpad
	private float[] mResults = new float[2];

	public void dump(Printer pw, String prefix) {
	pw.println(prefix + "mProvider=" + mProvider + " mTime=" + mTime);
	pw.println(prefix + "mLatitude=" + mLatitude + " mLongitude=" + mLongitude);
	pw.println(prefix + "mHasAltitude=" + mHasAltitude + " mAltitude=" + mAltitude);
	pw.println(prefix + "mHasSpeed=" + mHasSpeed + " mSpeed=" + mSpeed);
	pw.println(prefix + "mHasBearing=" + mHasBearing + " mBearing=" + mBearing);
	pw.println(prefix + "mHasAccuracy=" + mHasAccuracy + " mAccuracy=" + mAccuracy);
	pw.println(prefix + "mExtras=" + mExtras);
	}

	/**
	* Constructs a new Location. By default, time, latitude,
	* longitude, and numSatellites are 0; hasAltitude, hasSpeed, and
	* hasBearing are false; and there is no extra information.
	*
	* @param provider the name of the location provider that generated this
	* location fix.
	*/
	public Location(String provider) {
	mProvider = provider;
	}

	/**
	* Constructs a new Location object that is a copy of the given
	* location.
	*/
	public Location(Location l) {
	set(l);
	}

	/**
	* Sets the contents of the location to the values from the given location.
	*/
	public void set(Location l) {
	mProvider = l.mProvider;
	mTime = l.mTime;
	mLatitude = l.mLatitude;
	mLongitude = l.mLongitude;
	mHasAltitude = l.mHasAltitude;
	mAltitude = l.mAltitude;
	mHasSpeed = l.mHasSpeed;
	mSpeed = l.mSpeed;
	mHasBearing = l.mHasBearing;
	mBearing = l.mBearing;
	mHasAccuracy = l.mHasAccuracy;
	mAccuracy = l.mAccuracy;
	mExtras = (l.mExtras == null) ? null : new Bundle(l.mExtras);
	}

	/**
	* Clears the contents of the location.
	*/
	public void reset() {
	mProvider = null;
	mTime = 0;
	mLatitude = 0;
	mLongitude = 0;
	mHasAltitude = false;
	mAltitude = 0;
	mHasSpeed = false;
	mSpeed = 0;
	mHasBearing = false;
	mBearing = 0;
	mHasAccuracy = false;
	mAccuracy = 0;
	mExtras = null;
	}

	/**
	* Converts a coordinate to a String representation. The outputType
	* may be one of FORMAT_DEGREES, FORMAT_MINUTES, or FORMAT_SECONDS.
	* The coordinate must be a valid double between -180.0 and 180.0.
	*
	* @throws IllegalArgumentException if coordinate is less than
	* -180.0, greater than 180.0, or is not a number.
	* @throws IllegalArgumentException if outputType is not one of
	* FORMAT_DEGREES, FORMAT_MINUTES, or FORMAT_SECONDS.
	*/
	public static String convert(double coordinate, int outputType) {
	if (coordinate < -180.0 \|\| coordinate > 180.0 \|\|
	Double.isNaN(coordinate)) {
	throw new IllegalArgumentException("coordinate=" + coordinate);
	}
	if ((outputType != FORMAT_DEGREES) &&
	(outputType != FORMAT_MINUTES) &&
	(outputType != FORMAT_SECONDS)) {
	throw new IllegalArgumentException("outputType=" + outputType);
	}

	StringBuilder sb = new StringBuilder();

	// Handle negative values
	if (coordinate < 0) {
	sb.append('-');
	coordinate = -coordinate;
	}

	DecimalFormat df = new DecimalFormat("###.#####");
	if (outputType == FORMAT_MINUTES \|\| outputType == FORMAT_SECONDS) {
	int degrees = (int) Math.floor(coordinate);
	sb.append(degrees);
	sb.append(':');
	coordinate -= degrees;
	coordinate *= 60.0;
	if (outputType == FORMAT_SECONDS) {
	int minutes = (int) Math.floor(coordinate);
	sb.append(minutes);
	sb.append(':');
	coordinate -= minutes;
	coordinate *= 60.0;
	}
	}
	sb.append(df.format(coordinate));
	return sb.toString();
	}

	/**
	* Converts a String in one of the formats described by
	* FORMAT_DEGREES, FORMAT_MINUTES, or FORMAT_SECONDS into a
	* double.
	*
	* @throws NullPointerException if coordinate is null
	* @throws IllegalArgumentException if the coordinate is not
	* in one of the valid formats.
	*/
	public static double convert(String coordinate) {
	// IllegalArgumentException if bad syntax
	if (coordinate == null) {
	throw new NullPointerException("coordinate");
	}

	boolean negative = false;
	if (coordinate.charAt(0) == '-') {
	coordinate = coordinate.substring(1);
	negative = true;
	}

	StringTokenizer st = new StringTokenizer(coordinate, ":");
	int tokens = st.countTokens();
	if (tokens < 1) {
	throw new IllegalArgumentException("coordinate=" + coordinate);
	}
	try {
	String degrees = st.nextToken();
	double val;
	if (tokens == 1) {
	val = Double.parseDouble(degrees);
	return negative ? -val : val;
	}

	String minutes = st.nextToken();
	int deg = Integer.parseInt(degrees);
	double min;
	double sec = 0.0;

	if (st.hasMoreTokens()) {
	min = Integer.parseInt(minutes);
	String seconds = st.nextToken();
	sec = Double.parseDouble(seconds);
	} else {
	min = Double.parseDouble(minutes);
	}

	boolean isNegative180 = negative && (deg == 180) &&
	(min == 0) && (sec == 0);

	// deg must be in [0, 179] except for the case of -180 degrees
	if ((deg < 0.0) \|\| (deg > 179 && !isNegative180)) {
	throw new IllegalArgumentException("coordinate=" + coordinate);
	}
	if (min < 0 \|\| min > 59) {
	throw new IllegalArgumentException("coordinate=" +
	coordinate);
	}
	if (sec < 0 \|\| sec > 59) {
	throw new IllegalArgumentException("coordinate=" +
	coordinate);
	}

	val = deg3600.0 + min60.0 + sec;
	val /= 3600.0;
	return negative ? -val : val;
	} catch (NumberFormatException nfe) {
	throw new IllegalArgumentException("coordinate=" + coordinate);
	}
	}

	private static void computeDistanceAndBearing(double lat1, double lon1,
	double lat2, double lon2, float[] results) {
	// Based on http://www.ngs.noaa.gov/PUBS_LIB/inverse.pdf
	// using the "Inverse Formula" (section 4)

	int MAXITERS = 20;
	// Convert lat/long to radians
	lat1 *= Math.PI / 180.0;
	lat2 *= Math.PI / 180.0;
	lon1 *= Math.PI / 180.0;
	lon2 *= Math.PI / 180.0;

	double a = 6378137.0; // WGS84 major axis
	double b = 6356752.3142; // WGS84 semi-major axis
	double f = (a - b) / a;
	double aSqMinusBSqOverBSq = (a * a - b * b) / (b * b);

	double L = lon2 - lon1;
	double A = 0.0;
	double U1 = Math.atan((1.0 - f) * Math.tan(lat1));
	double U2 = Math.atan((1.0 - f) * Math.tan(lat2));

	double cosU1 = Math.cos(U1);
	double cosU2 = Math.cos(U2);
	double sinU1 = Math.sin(U1);
	double sinU2 = Math.sin(U2);
	double cosU1cosU2 = cosU1 * cosU2;
	double sinU1sinU2 = sinU1 * sinU2;

	double sigma = 0.0;
	double deltaSigma = 0.0;
	double cosSqAlpha = 0.0;
	double cos2SM = 0.0;
	double cosSigma = 0.0;
	double sinSigma = 0.0;
	double cosLambda = 0.0;
	double sinLambda = 0.0;

	double lambda = L; // initial guess
	for (int iter = 0; iter < MAXITERS; iter++) {
	double lambdaOrig = lambda;
	cosLambda = Math.cos(lambda);
	sinLambda = Math.sin(lambda);
	double t1 = cosU2 * sinLambda;
	double t2 = cosU1 * sinU2 - sinU1 * cosU2 * cosLambda;
	double sinSqSigma = t1 * t1 + t2 * t2; // (14)
	sinSigma = Math.sqrt(sinSqSigma);
	cosSigma = sinU1sinU2 + cosU1cosU2 * cosLambda; // (15)
	sigma = Math.atan2(sinSigma, cosSigma); // (16)
	double sinAlpha = (sinSigma == 0) ? 0.0 :
	cosU1cosU2 * sinLambda / sinSigma; // (17)
	cosSqAlpha = 1.0 - sinAlpha * sinAlpha;
	cos2SM = (cosSqAlpha == 0) ? 0.0 :
	cosSigma - 2.0 * sinU1sinU2 / cosSqAlpha; // (18)

	double uSquared = cosSqAlpha * aSqMinusBSqOverBSq; // defn
	A = 1 + (uSquared / 16384.0) * // (3)
	(4096.0 + uSquared *
	(-768 + uSquared * (320.0 - 175.0 * uSquared)));
	double B = (uSquared / 1024.0) * // (4)
	(256.0 + uSquared *
	(-128.0 + uSquared * (74.0 - 47.0 * uSquared)));
	double C = (f / 16.0) *
	cosSqAlpha *
	(4.0 + f * (4.0 - 3.0 * cosSqAlpha)); // (10)
	double cos2SMSq = cos2SM * cos2SM;
	deltaSigma = B * sinSigma * // (6)
	(cos2SM + (B / 4.0) *
	(cosSigma * (-1.0 + 2.0 * cos2SMSq) -
	(B / 6.0) * cos2SM *
	(-3.0 + 4.0 * sinSigma * sinSigma) *
	(-3.0 + 4.0 * cos2SMSq)));

	lambda = L +
	(1.0 - C) * f * sinAlpha *
	(sigma + C * sinSigma *
	(cos2SM + C * cosSigma *
	(-1.0 + 2.0 * cos2SM * cos2SM))); // (11)

	double delta = (lambda - lambdaOrig) / lambda;
	if (Math.abs(delta) < 1.0e-12) {
	break;
	}
	}

	float distance = (float) (b * A * (sigma - deltaSigma));
	results[0] = distance;
	if (results.length > 1) {
	float initialBearing = (float) Math.atan2(cosU2 * sinLambda,
	cosU1 * sinU2 - sinU1 * cosU2 * cosLambda);
	initialBearing *= 180.0 / Math.PI;
	results[1] = initialBearing;
	if (results.length > 2) {
	float finalBearing = (float) Math.atan2(cosU1 * sinLambda,
	-sinU1 * cosU2 + cosU1 * sinU2 * cosLambda);
	finalBearing *= 180.0 / Math.PI;
	results[2] = finalBearing;
	}
	}
	}

	/**
	* Computes the approximate distance in meters between two
	* locations, and optionally the initial and final bearings of the
	* shortest path between them. Distance and bearing are defined using the
	* WGS84 ellipsoid.
	*
	* <p> The computed distance is stored in results[0]. If results has length
	* 2 or greater, the initial bearing is stored in results[1]. If results has
	* length 3 or greater, the final bearing is stored in results[2].
	*
	* @param startLatitude the starting latitude
	* @param startLongitude the starting longitude
	* @param endLatitude the ending latitude
	* @param endLongitude the ending longitude
	* @param results an array of floats to hold the results
	*
	* @throws IllegalArgumentException if results is null or has length < 1
	*/
	public static void distanceBetween(double startLatitude, double startLongitude,
	double endLatitude, double endLongitude, float[] results) {
	if (results == null \|\| results.length < 1) {
	throw new IllegalArgumentException("results is null or has length < 1");
	}
	computeDistanceAndBearing(startLatitude, startLongitude,
	endLatitude, endLongitude, results);
	}

	/**
	* Returns the approximate distance in meters between this
	* location and the given location. Distance is defined using
	* the WGS84 ellipsoid.
	*
	* @param dest the destination location
	* @return the approximate distance in meters
	*/
	public float distanceTo(Location dest) {
	// See if we already have the result
	synchronized (mResults) {
	if (mLatitude != mLat1 \|\| mLongitude != mLon1 \|\|
	dest.mLatitude != mLat2 \|\| dest.mLongitude != mLon2) {
	computeDistanceAndBearing(mLatitude, mLongitude,
	dest.mLatitude, dest.mLongitude, mResults);
	mLat1 = mLatitude;
	mLon1 = mLongitude;
	mLat2 = dest.mLatitude;
	mLon2 = dest.mLongitude;
	mDistance = mResults[0];
	mInitialBearing = mResults[1];
	}
	return mDistance;
	}
	}

	/**
	* Returns the approximate initial bearing in degrees East of true
	* North when traveling along the shortest path between this
	* location and the given location. The shortest path is defined
	* using the WGS84 ellipsoid. Locations that are (nearly)
	* antipodal may produce meaningless results.
	*
	* @param dest the destination location
	* @return the initial bearing in degrees
	*/
	public float bearingTo(Location dest) {
	synchronized (mResults) {
	// See if we already have the result
	if (mLatitude != mLat1 \|\| mLongitude != mLon1 \|\|
	dest.mLatitude != mLat2 \|\| dest.mLongitude != mLon2) {
	computeDistanceAndBearing(mLatitude, mLongitude,
	dest.mLatitude, dest.mLongitude, mResults);
	mLat1 = mLatitude;
	mLon1 = mLongitude;
	mLat2 = dest.mLatitude;
	mLon2 = dest.mLongitude;
	mDistance = mResults[0];
	mInitialBearing = mResults[1];
	}
	return mInitialBearing;
	}
	}

	/**
	* Returns the name of the provider that generated this fix,
	* or null if it is not associated with a provider.
	*/
	public String getProvider() {
	return mProvider;
	}

	/**
	* Sets the name of the provider that generated this fix.
	*/
	public void setProvider(String provider) {
	mProvider = provider;
	}

	/**
	* Returns the UTC time of this fix, in milliseconds since January 1,
	* 1970.
	*/
	public long getTime() {
	return mTime;
	}

	/**
	* Sets the UTC time of this fix, in milliseconds since January 1,
	* 1970.
	*/
	public void setTime(long time) {
	mTime = time;
	}

	/**
	* Returns the latitude of this fix.
	*/
	public double getLatitude() {
	return mLatitude;
	}

	/**
	* Sets the latitude of this fix.
	*/
	public void setLatitude(double latitude) {
	mLatitude = latitude;
	}

	/**
	* Returns the longitude of this fix.
	*/
	public double getLongitude() {
	return mLongitude;
	}

	/**
	* Sets the longitude of this fix.
	*/
	public void setLongitude(double longitude) {
	mLongitude = longitude;
	}

	/**
	* Returns true if this fix contains altitude information, false
	* otherwise.
	*/
	public boolean hasAltitude() {
	return mHasAltitude;
	}

	/**
	* Returns the altitude of this fix. If {@link #hasAltitude} is false,
	* 0.0f is returned.
	*/
	public double getAltitude() {
	return mAltitude;
	}

	/**
	* Sets the altitude of this fix. Following this call,
	* hasAltitude() will return true.
	*/
	public void setAltitude(double altitude) {
	mAltitude = altitude;
	mHasAltitude = true;
	}

	/**
	* Clears the altitude of this fix. Following this call,
	* hasAltitude() will return false.
	*/
	public void removeAltitude() {
	mAltitude = 0.0f;
	mHasAltitude = false;
	}

	/**
	* Returns true if this fix contains speed information, false
	* otherwise. The default implementation returns false.
	*/
	public boolean hasSpeed() {
	return mHasSpeed;
	}

	/**
	* Returns the speed of the device over ground in meters/second.
	* If hasSpeed() is false, 0.0f is returned.
	*/
	public float getSpeed() {
	return mSpeed;
	}

	/**
	* Sets the speed of this fix, in meters/second. Following this
	* call, hasSpeed() will return true.
	*/
	public void setSpeed(float speed) {
	mSpeed = speed;
	mHasSpeed = true;
	}

	/**
	* Clears the speed of this fix. Following this call, hasSpeed()
	* will return false.
	*/
	public void removeSpeed() {
	mSpeed = 0.0f;
	mHasSpeed = false;
	}

	/**
	* Returns true if the provider is able to report bearing information,
	* false otherwise. The default implementation returns false.
	*/
	public boolean hasBearing() {
	return mHasBearing;
	}

	/**
	* Returns the direction of travel in degrees East of true
	* North. If hasBearing() is false, 0.0 is returned.
	*/
	public float getBearing() {
	return mBearing;
	}

	/**
	* Sets the bearing of this fix. Following this call, hasBearing()
	* will return true.
	*/
	public void setBearing(float bearing) {
	while (bearing < 0.0f) {
	bearing += 360.0f;
	}
	while (bearing >= 360.0f) {
	bearing -= 360.0f;
	}
	mBearing = bearing;
	mHasBearing = true;
	}

	/**
	* Clears the bearing of this fix. Following this call, hasBearing()
	* will return false.
	*/
	public void removeBearing() {
	mBearing = 0.0f;
	mHasBearing = false;
	}

	/**
	* Returns true if the provider is able to report accuracy information,
	* false otherwise. The default implementation returns false.
	*/
	public boolean hasAccuracy() {
	return mHasAccuracy;
	}

	/**
	* Returns the accuracy of the fix in meters. If hasAccuracy() is false,
	* 0.0 is returned.
	*/
	public float getAccuracy() {
	return mAccuracy;
	}

	/**
	* Sets the accuracy of this fix. Following this call, hasAccuracy()
	* will return true.
	*/
	public void setAccuracy(float accuracy) {
	mAccuracy = accuracy;
	mHasAccuracy = true;
	}

	/**
	* Clears the accuracy of this fix. Following this call, hasAccuracy()
	* will return false.
	*/
	public void removeAccuracy() {
	mAccuracy = 0.0f;
	mHasAccuracy = false;
	}

	/**
	* Returns additional provider-specific information about the
	* location fix as a Bundle. The keys and values are determined
	* by the provider. If no additional information is available,
	* null is returned.
	*
	* <p> A number of common key/value pairs are listed
	* below. Providers that use any of the keys on this list must
	* provide the corresponding value as described below.
	*
	* <ul>
	* <li> satellites - the number of satellites used to derive the fix
	* </ul>
	*/
	public Bundle getExtras() {
	return mExtras;
	}

	/**
	* Sets the extra information associated with this fix to the
	* given Bundle.
	*/
	public void setExtras(Bundle extras) {
	mExtras = (extras == null) ? null : new Bundle(extras);
	}

	@Override public String toString() {
	return "Location[mProvider=" + mProvider +
	",mTime=" + mTime +
	",mLatitude=" + mLatitude +
	",mLongitude=" + mLongitude +
	",mHasAltitude=" + mHasAltitude +
	",mAltitude=" + mAltitude +
	",mHasSpeed=" + mHasSpeed +
	",mSpeed=" + mSpeed +
	",mHasBearing=" + mHasBearing +
	",mBearing=" + mBearing +
	",mHasAccuracy=" + mHasAccuracy +
	",mAccuracy=" + mAccuracy +
	",mExtras=" + mExtras + "]";
	}

	public static final Parcelable.Creator<Location> CREATOR =
	new Parcelable.Creator<Location>() {
	public Location createFromParcel(Parcel in) {
	String provider = in.readString();
	Location l = new Location(provider);
	l.mTime = in.readLong();
	l.mLatitude = in.readDouble();
	l.mLongitude = in.readDouble();
	l.mHasAltitude = in.readInt() != 0;
	l.mAltitude = in.readDouble();
	l.mHasSpeed = in.readInt() != 0;
	l.mSpeed = in.readFloat();
	l.mHasBearing = in.readInt() != 0;
	l.mBearing = in.readFloat();
	l.mHasAccuracy = in.readInt() != 0;
	l.mAccuracy = in.readFloat();
	l.mExtras = in.readBundle();
	return l;
	}

	public Location[] newArray(int size) {
	return new Location[size];
	}
	};

	public int describeContents() {
	return 0;
	}

	public void writeToParcel(Parcel parcel, int flags) {
	parcel.writeString(mProvider);
	parcel.writeLong(mTime);
	parcel.writeDouble(mLatitude);
	parcel.writeDouble(mLongitude);
	parcel.writeInt(mHasAltitude ? 1 : 0);
	parcel.writeDouble(mAltitude);
	parcel.writeInt(mHasSpeed ? 1 : 0);
	parcel.writeFloat(mSpeed);
	parcel.writeInt(mHasBearing ? 1 : 0);
	parcel.writeFloat(mBearing);
	parcel.writeInt(mHasAccuracy ? 1 : 0);
	parcel.writeFloat(mAccuracy);
	parcel.writeBundle(mExtras);
	}
	}