The Answer by Antonio is correct and should be accepted (click the big empty check mark).
This Answer adds some thoughts and example code.
Avoid 3-Letter Time Zone Codes
Avoid using, or even thinking about, those 3 or 4 letter codes such as
PST. They are not standardized, they are not unique, and they further confuse issues around Daylight Saving Time (DST). For example, IST means "India Standard Time", "Irish Standard Time", and more.
Use proper time zone names. Most of these are in a "continent" + "/" + "city/region" pattern. The city/region name is not meant specifically for that town, but rather as an easily identifiable name for as wide an area as possible that shares the same set of past, present, and future rules for time zone rules and anomalies (including DST).
Generally you should be using UTC time zone for all your business logic, data storage, and data exchange. Adjust to a particular time zone only for presentation when expected by the user.
Use A Decent Date-Time Framework
The old java.util.Date/.Calendar classes were a bold attempt at handling date-time work, but ultimately they failed. They are notoriously troublesome, flawed in both design and implementation. Avoid them.
The 3rd-party Joda-Time library is one solution. It works in many versions of Java and also in Android. Joda-Time inspired the other solution, the java.time package found in Java 8 and later (Tutorial).
The Question seems to have a goal of taking a java.util.Date object, assign desired time zone, and produce a java.util.Calendar object.
Fortunately the java.time framework has conversion methods. See this Tutorial page.
Example code follows, using java.time from Java 8 Update 45.
You may want imports such as:
Let's simulate getting a java.util.Date passed in. We'll instantiate a Date based on "now".
Date inputDate = new Date( ); // Simulate getting a java.util.Date object.
Then we define the desired time zones, using proper time zone names. Let’s throw in Montréal just for fun as well as the pacific United States and India time zones mentioned in the Question.
ZoneId zoneLosAngeles = ZoneId.of( "America/Los_Angeles" );
ZoneId zoneMontréal = ZoneId.of( "America/Montreal" );
ZoneId zoneKolkata = ZoneId.of( "Asia/Kolkata" );
Then we convert that to an
Instant, a point on the timeline without regard to time zone.
Instant instant = inputDate.toInstant( );
Then we assign various time zones to create
ZonedDateTime instances. See how we can instantiate a ZonedDateTime in either of two ways: [a] from an Instant, or [b] from another ZonedDateTime via the
withZoneSameInstant method. Both ways are shown below.
Note that java.time (and Joda-Time) uses immutable objects, a design pattern where we create new instances based on the old instance rather than alter ("mutate") the old instance. Thread-safety is one of the major benefits.
ZonedDateTime zdtLosAngeles = ZonedDateTime.ofInstant( instant, zoneLosAngeles );
ZonedDateTime zdtMontréal = ZonedDateTime.ofInstant( instant, zoneMontréal );
ZonedDateTime zdtKolkata = ZonedDateTime.ofInstant( instant, zoneKolkata );
ZonedDateTime zdtUtc = zdtKolkata.withZoneSameInstant( ZoneOffset.UTC );
Lastly, we convert one of those to a
GregorianCalendar object which is a subclass of
GregorianCalendar calendarKolkata = GregorianCalendar.from( zdtKolkata );
Dump to console.
System.out.println( "inputDate: " + inputDate );
System.out.println( "zdtLosAngeles: " + zdtLosAngeles );
System.out.println( "zdtMontréal: " + zdtMontréal );
System.out.println( "zdtKolkata: " + zdtKolkata );
System.out.println( "zdtUtc: " + zdtUtc );
System.out.println( "calendarKolkata: " + calendarKolkata );
inputDate: Wed Jun 24 15:12:12 PDT 2015