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Chapter 7 Basic Utility Classes |
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Chapter 7 Basic Utility Classes |
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As I described in Chapter 1, Yet Another Language?, a Java application's access to system resources, such as the display, the filesystem, threads, external processes, and the network, can be controlled at a single point with a security manager. The class that implements this functionality in the Java API is the java.lang.SecurityManager class.
An instance of the SecurityManager class can be installed once, and only once, in the life of the Java run-time environment. Thereafter, every access to a fundamental system resource is filtered through specific methods of the SecurityManager object by the core Java packages. By installing a specialized SecurityManager, we can implement arbitrarily complex (or simple) security policies for allowing access to individual resources.
When the Java run-time system starts executing, it's in a wide-open state until a SecurityManager is installed. The "null" security manager grants all requests, so the Java virtual environment can perform any activity with the same level of access as other programs running under the user's authority. If the application that is running needs to ensure a secure environment, it can install a SecurityManager with the static System.setSecurityManager() method. For example, a Java-enabled Web browser like Netscape Navigator installs a SecurityManager before it runs any Java applets.
java.lang.SecurityManager must be subclassed to be used. This class does not actually contain any abstract methods; it's abstract as an indication that its default implementation is not very useful. By default, each security method in SecurityManager is implemented to provide the strictest level of security. In other words, the default SecurityManager simply rejects all requests.
The following example, MyApp, installs a trivial subclass of SecurityManager as one of its first activities:
class FascistSecurityManager extends SecurityManager { }
public class MyApp {
public static void main( Strings [] args ) {
System.setSecurityManager( new FascistSecurityManager() );
// No access to files, network, windows, etc.
...
}
}
In the above scenario, MyApp does little aside from reading from System.in and writing to System.out. Any attempts to read or write files, access the network, or even open an window, results in a SecurityException being thrown.
After this draconian SecurityManager is installed, it's impossible to change the SecurityManager in any way. The security of this feature is not dependent on the SecurityManager; you can't replace or modify the SecurityManager under any circumstances. The upshot of this is that you have to install one that handles all your needs up front.
To do something more useful, we can override the methods that are consulted for access to various kinds of resources. Table 7.7 lists some of the more important access methods. You should not normally have to call these methods yourself, although you could. They are called by the core Java classes before granting particular types of access.
| Method | Can I...? |
|---|---|
| checkAccess(Thread g) | Access this thread? |
| checkExit(int status) | Execute a System.exit()? |
| checkExec(String cmd) | exec() this process? |
| checkRead(String file) | Read a file? |
| checkWrite(String file) | Write a file? |
| checkDelete(String file) | Delete a file? |
| checkConnect(String host, int port) | Connect a socket to a host? |
| checkListen(int port) | Create a server socket? |
| checkAccept(String host, int port) | Accept this connection? |
| checkPropertyAccess(String key) | Access this system property? |
| checkTopLevelWindow(Object window) | Create this new top-level window? |
All these methods, with the exception of checkTopLevelWindow(), simply return to grant access. If access is not granted, they throw a SecurityException. checkTopLevelWindow() returns a boolean value. A value of true indicates the access is granted; a value of false indicates the access is granted with the restriction that the new window should provide a warning border that serves to identify it as an untrusted window.
Let's implement a silly SecurityManager that allows only files beginning with the name foo to be read:
class FooFileSecurityManager extends SecurityManager {
public void checkRead( String s ) {
if ( !s.startsWith("foo") )
throw new SecurityException("Access to non-foo file: " +
s + " not allowed." );
}
}
Once the FooFileSecurityManager is installed, any attempt to read a filename other than foo* from any class will fail and cause a SecurityException to be thrown. All other security methods are inherited from SecurityManager, so they are left at their default restrictiveness.
All restrictions placed on applets by an applet-viewer application are enforced through a SecurityManager, which allows untrusted code loaded from over the network to be executed safely. The restrictions placed on applets are currently fairly harsh. As time passes and security considerations related to applets are better understood and accepted, the applet API will hopefully become more powerful and allow forms of persistence and access to designated public information.
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