According to \[[API 06|AA. Java References#API 06]\], Class {{SecurityManager}} documentation:to the Java API Class Wiki Markup SecurityManager
documentation [API 2014],
The security manager is a class that allows applications to implement a security policy. It allows an application to determine, before performing a possibly unsafe or sensitive operation, what the operation is and whether it is being attempted in a security context that allows the operation to be performed. The application can allow or disallow the operation..
A security manager may be associated with any Java code.
The applet As an example, the security manager denies applets all but the most essential privileges. It is designed to protect against inadvertent system modification, information leakage, and user impersonation. The use of security managers is not limited to client-side protection. Web servers, such as Tomcat and WebSphere, use this facility to isolate trojan servlets and malicious Java Server Pages (JSP) code as well as to protect sensitive system resources from inadvertent access.
Java applications that run from the command line can set a default or custom security manager using a command-line flag. Alternatively, it is possible to install a security manager programmatically. Installing a security manager programmatically helps create a default sandbox that allows or denies sensitive actions on the basis of the security policy in effect.
From Java 2 SE Platform onwardsonward, SecurityManager
is a non-abstract nonabstract class. As a result, there is no explicit requirement of overriding to override its methods. To create and use a security manager programmatically, the code must have the runtime permissions createSecurityManager
(to instantiate SecurityManager
and avoid certain information leakage) and setSecurityManager
(to install it.
Noncompliant Code Example
The worst form of non-compliance is not using the the security manager at all. Even when used, there can be cases where the appropriate checks are not installed. In the noncompliant code that follows, a null
value has been passed to the setSecurityManager
method that is responsible for establishing a current instance of SecurityManager
. Moreover, the checkPermission
(or any check*
) method has not been used.
Code Block | ||
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try {
System.setSecurityManager(null);
} catch (SecurityException se) { System.out.println("SecurityManager is already set!"); }
|
). These permissions are checked only if a security manager is already installed. This is useful for situations in which a default security manager is in place, such as on a virtual host, and individual hosts must be denied the requisite permissions for overriding the default security manager with a custom one.
The security manager is closely tied to the AccessController
class. The former is used as a hub for access control, whereas the latter provides the actual implementation of the access control algorithm. The security manager supports
- Providing backward compatibility: Legacy code often contains custom implementations of the security manager class because it was originally abstract.
- Defining custom policies: Subclassing the security manager permits definition of custom security policies (for example, multilevel, coarse, or fine grain).
Regarding the implementation and use of custom security managers as opposed to default ones, the Java security architecture specification [SecuritySpec 2010] states:
We encourage the use of
AccessController
in application code, while customization of a security manager (via subclassing) should be the last resort and should be done with extreme care. Moreover, a customized security manager, such as one that always checks the time of the day before invoking standard security checks, could and should utilize the algorithm provided byAccessController
whenever appropriate.
Many of the Java SE APIs perform security manager checks by default before performing sensitive operations. For example, the constructor of class java.io.FileInputStream
throws a SecurityException
if the caller does not have the permission to read a file. Because SecurityException
is a subclass of RuntimeException
, the declarations of some API methods (for example, those of the java.io.FileReader
class) may lack a throws
clause that lists the SecurityException
. Avoid depending on the presence or absence of security manager checks that are not specified in the API method's documentation.
Noncompliant Code Example (Command-Line Installation)
This noncompliant code example fails to install any security manager from the command line. Consequently, the program runs with all permissions enabled; that is, there is no security manager to prevent any nefarious actions the program might performAny Java program (bean, servlet or application) can instantiate a SecurityManager
. However, for applications designed to run locally, an explicit flag must be set to enforce the SecurityManager
policy. In the noncompliant example highlighted next, this flag has not been used which circumvents all SecurityManager
checks.
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java applicationLocalJavaApp |
Compliant Solution
...
(Default Policy File)
Any Java program can attempt to install a SecurityManager
programmatically, although the currently active security manager may forbid this operation. Applications designed to run locally can specify a default security manager by use of a flag on the command line at invocation.
The command-line option is preferred when applications must be prohibited from installing custom security managers programmatically and are required to abide by the default global security policy under all circumstances. This compliant solution installs the default security manager using the appropriate command-line flags. The security policy file grants permissions to the application for its intended actions.This compliant solution demonstrates how a custom SecurityManager
class called CustomSecurityManager
can be activated by invoking its constructor with a password. Various check methods defined within the class can then be invoked to perform access checks. Alternatively, to use the default security manager change the active instance to java.lang.SecurityManager
.
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try { System.setSecurityManager(new CustomSecurityManager("password here"));java -Djava.security.manager -Djava.security.policy=policyURL \ SecurityManager sm = System.getSecurityManager(); if(sm != null) { //check if file can be read FilePermission perm = new FilePermission("/temp/tempFile", "read"); sm.checkPermission(perm); } } catch (SecurityException se) { System.out.println("SecurityManager is already set!"); } LocalJavaApp |
The command-line flag can specify a custom security manager whose policies are enforced globally. Use the -Djava.security.manager
flag, as follows:
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java -Djava.security.manager=my.security.CustomManager ...
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If the current security policy enforced by the current security manager forbids replacements (by omitting the RuntimePermission("setSecurityManager")
), any attempt to invoke setSecurityManager()
will throw a SecurityException
.
The default security policy file java.policy
—found in the /path/to/java.home/lib/security
directory on UNIX-like systems and its equivalent on Microsoft Windows systems—grants a few permissions (reading system properties, binding to unprivileged ports, and so forth). A user-specific policy file may be located in the user's home directory. The union of these policy files specifies the permissions granted to a program. The java.security
file can specify which policy files are used. If either of the systemwide java.policy
or java.security
files is deleted, no permissions are granted to the executing Java program.
Compliant Solution (Custom Policy File)
Use double equals (==
) instead of the single equals (=
) when overriding the global Java security policy file with a custom policy file:
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java -Djava.security.manager \
-Djava.security.policy==policyURL \
LocalJavaApp
|
Compliant Solution (Additional Policy Files)
The appletviewer
automatically installs a security manager with the standard policy file. To specify additional policy files, use the -J
For local applications, the security manager can be installed using the flags as shown next. Note that the setSecurityManager
method must be replaced by getSecurityManager
in this case since the manager has already been installed using the command line flag.
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javaappletviewer -J-Djava.security.manager \ -J-Djava.security.policy==policyURL LocalJavaApp |
By default, the SecurityManager
checkPermission
method(s) forward all calls to the java.security.Accesscontroller.checkPermission
. Sometimes it is required to perform checks against a different context than the currently executing threads' context. This can be done using the checkPermission(Permission perm, Object context)
method which takes an extra argument (like AccessControlContext)
as the context of the desired thread.
Wiki Markup |
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The default policy file {{java.policy}} grants a few permissions (reading system properties, binding to unprivileged ports and so on) and can be found in the {{~/java.home/lib/security}} directory on *nix based systems and its equivalent on Microsoft Windows systems. The document \[[Policy 02|AA. Java References#Policy 02]\] discusses writing policy files in depth. |
Risk Assessment
Running Java code without a Security Manager being set means that there is no security at all.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
SEC30-J | high | probable | low | P18 | L1 |
Automated Detection
TODO
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
References
Wiki Markup |
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\[[API 06|AA. Java References#API 06]\] [Class SecurityManager|http://java.sun.com/javase/6/docs/api/java/lang/SecurityManager.html]
\[[Policy 02|AA. Java References#Policy 02]\]
\[[Pistoia 04|AA. Java References#Pistoia 04]\] Section 7.4, The Security Manager
\[[Gong 03|AA. Java References#Gong 03]\] Section 6.1, Security Manager |
Note that the policy file specified in the argument is ignored when the policy.allowSystemProperty
property in the security properties file (java.security
) is set to false
; the default value of this property is true
. Default Policy Implementation and Policy File Syntax [Policy 2010] discusses in depth the issues of and syntax for writing policy files.
Noncompliant Code Example (Programmatic Installation)
A SecurityManager
can also be activated using the static System.setSecurityManager()
method. Only one SecurityManager
may be active at a time. This method replaces the currently active SecurityManager
with the SecurityManager
provided in its argument or no SecurityManager
if its argument is null
.
This noncompliant code example deactivates any current SecurityManager
but does not install another SecurityManager
in its place. Consequently, subsequent code will run with all permissions enabled; there will be no restrictions on any nefarious action the program might perform.
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try {
System.setSecurityManager(null);
} catch (SecurityException se) {
// Cannot set security manager, log to file
}
|
An active SecurityManager
that enforces a sensible security policy will prevent the system from deactivating it, causing this code to throw a SecurityException
.
Compliant Solution (Default Security Manager)
This compliant solution instantiates and sets the default security manager:
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try {
System.setSecurityManager(new SecurityManager());
} catch (SecurityException se) {
// Cannot set security manager, log appropriately
}
|
Compliant Solution (Custom Security Manager)
This compliant solution demonstrates how to instantiate a custom SecurityManager
class called CustomSecurityManager
by invoking its constructor with a password; this custom security manager is then installed as the active security manager.
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char password[] = /* initialize */
try {
System.setSecurityManager(
new CustomSecurityManager("password here")
);
} catch (SecurityException se) {
// Cannot set security manager, log appropriately
}
|
After this code executes, APIs that perform security checks use the custom security manager. As noted earlier, custom security managers should be installed only when the default security manager lacks the required functionality.
Applicability
Java security fundamentally depends on the existence of a security manager. In its absence, sensitive actions can execute without restriction.
Programmatic detection of the presence or absence of a SecurityManager
at runtime is straightforward. Static analysis can address the presence or absence of code that would attempt to install a SecurityManager
if the code were executed. Checking whether the SecurityManager
is installed early enough, whether it specifies the desired properties, or whether it is guaranteed to be installed may be possible in some special cases but is generally undecidable.
Bibliography
[API 2014] | Class SecurityManager Class AccessControlContext Class AccessController |
[Gong 2003] | §6.1, "Security Manager" |
[Pistoia 2004] | §7.4, "The Security Manager" |
[Policy 2010] | Default Policy Implementation and Policy File Syntax |
[SecuritySpec 2010] | §6.2, "SecurityManager versus AccessController " |
...
SEC07-J. Minimize accessibility 00. Security (SEC) SEC31-J. Never grant AllPermission to untrusted code