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Each thread in Java is assigned to a thread group upon the thread's creation. These groups are implemented by the java.lang.ThreadGroup
class. When the thread group name is not specified explicitly, the main
default group is assigned by the Java Virtual Machine (JVM) [Java Tutorials]. The convenience methods of the ThreadGroup
class can be used to operate on all threads belonging to a thread group at once. For instance, the ThreadGroup.interrupt()
method interrupts all threads in the thread group. Thread groups also help reinforce layered security by confining threads into groups so that they avoid interference with threads in other groups [JavaThreads 2004].
Even though thread groups are useful for keeping threads organized, programmers seldom benefit from their use because many of the methods of the ThreadGroup
class (for example, allowThreadSuspension()
, resume()
, stop()
, and suspend()
) are deprecated. Furthermore, many nondeprecated methods are obsolete in that they offer little desirable functionality. Ironically, a few ThreadGroup
methods are not even thread-safe [Bloch 2001].
Insecure yet nondeprecated methods include
ThreadGroup.activeCount()
According to the Java API [API 2014], theactiveCount()
method
This method is often used as a precursor to thread enumeration. Threads that have never started nevertheless reside in the thread group and are considered to be active. The active count is also affected by the presence of certain system threads [API 2014]. Consequently, thereturns an estimate of the number of active threads in the current thread's thread group and its subgroups.
activeCount()
method might fail to reflect the actual number of running tasks in the thread group.
ThreadGroup.enumerate()
According to the Java API [API 2014],ThreadGroup
class documentation[The
enumerate()
method] copies into the specified array every active thread in this thread group and its subgroups....
An application might use theactiveCount
method to get an estimate of how big the array should be; however, if the array is too short to hold all the threads, the extra threads are silently ignored.
Using the ThreadGroup
APIs to shut down threads also has pitfalls. Because the stop()
method is deprecated, programs require alternative methods to stop threads. According to The Java Programming Language [JPL 2006]:
One way is for the thread initiating the termination to join the other threads and so know when those threads have terminated. However, an application may have to maintain its own list of the threads it creates because simply inspecting the
ThreadGroup
may return library threads that do not terminate and for which join will not return.
The Executor
framework provides a better API for managing a logical grouping of threads and offers secure facilities for handling shutdown and thread exceptions [Bloch 2008]. Consequently, programs must not invoke ThreadGroup
methods.
Noncompliant Code Example
This noncompliant code example contains a NetworkHandler
class that maintains a controller
thread. The controller
thread delegates each new request to a worker thread. To demonstrate the race condition in this example, the controller
thread serves three requests by starting three threads in succession from its run()
method. All threads are defined to belong to the Chief
thread group.
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final class HandleRequest implements Runnable { public void run() { // Do something } } public final }}. A group is assigned to a thread upon its creation. If the group name is not specified explicitly, the default group called {{main}} is assigned by the Java Virtual Machine (JVM). The convenience methods of the {{ThreadGroup}} class can be used to operate on all threads at once, such as, by using the {{interrupt()}} method. Another use is to reinforce layered security by confining threads into groups so that they do not interfere with each other. \[[JavaThreads 04|AA. Java References#JavaThreads 04]\] While there may be a few benefits, the associated dangers demand deeper insight into the real utility of the {{ThreadGroup}} class. Several of the {{ThreadGroup}} APIs ({{allowThreadSuspension, resume, stop, suspend}}) have been deprecated and the remainder are seldom used because they offer little desirable functionality. Ironically, a few APIs are not even thread-safe. \[[Bloch 01|AA. Java References#Bloch 01]\] A programmer may sometimes wish to enumerate all the threads in a group as a precursor to other operations. This is accomplished by using the {{activeCount()}} method that "Returns an estimate of the number of active threads in this thread group. " \[[API 06|AA. Java References#API 06]\]. Notice that there is no absolute word on whether it returns the exact count or not; the definition of _active_ also has a different connotation here. A thread that is constructed and not started is still counted by the {{activeCount()}} method as _active_. According to the Java API \[[API 06|AA. Java References#API 06]\], class {{ThreadGroup}} documentation: {quote} \[The {{enumerate}} method\] Copies into the specified array every active thread in this thread group and its subgroups. An application should use the {{activeCount}} method to get an estimate of how big the array should be. If the array is too short to hold all the threads, the extra threads are silently ignored. {quote} Threads are removed from the thread array either when they are stopped or when their {{run()}} method has finished executing. As a result, if a thread is not started, it continues to reside in the array despite the loss of the original reference. \[[JavaThreads 99|AA. Java References#JavaThreads 99]\] Using the {{ThreadGroup}} APIs to facilitate thread shutdown also has pitfalls. "One way is for the thread initiating the termination to join the other threads and so know when those threads have terminated. However, an application may have to maintain its own list of the threads it creates because simply inspecting the {{ThreadGroup}} may return library threads that do not terminate and for which join will not return." \[[JPL 06|AA. Java References#JPL 06]\]. h2. Noncompliant Code Example This noncompliant code example shows a {{NetworkHandler}} class that maintains a _controller_ thread {{t}}. This thread is responsible for spawning a new thread every time a new network connection request is received. For the sake of brevity, it is assumed that the _controller_ thread {{t}} services these requests by starting three nonterminating threads in succession and waiting for a few seconds. All threads are defined to belong to the same group, {{Chief}}. {mc} The other surprise is that after enumerating array ta, Chief also consists of a thread called "main" {mc} {code:bgColor=#FFcccc} class NetworkHandler implements Runnable { private static ThreadGroup tg = new ThreadGroup("Chief"); @Override public void run() { try { new Thread(tg, new HandleRequest(), "t1thread1").start(); // Start t1 new Thread(tg, new HandleRequest(), "t2thread2").start(); // Start t2 new Thread(tg, new HandleRequest(), "t3thread3").start(); // Start t3 Thread.sleep(2000); } catch(InterruptedException e) { // Forward to handler } } public static void printThreadsprintActiveCount(Thread t, int point) { System.out.println("Active Threads in Thread Group " + t.getThreadGroup()tg.getName() + " at point(" + point + "):" + " " + ttg.activeCount()); } public static void printEnumeratedThreads(Thread[] ta, int len) { System.out.println("Enumerating all threads..."); for (int i = 0; i < len; i++) { System.out.println("Thread " + i + " = " + ta[i].getName()); } } public static void main(String[] args) throws InterruptedException { // Start thread controller Thread tthread = new Thread(tg, new NetworkHandler(), "tcontroller"); tthread.start(); // Gets the active count (insecure) Thread[] ta = new Thread[ttg.activeCount()]; printThreadsprintActiveCount(t, 1); // At point 1 P1 Thread.sleep(1000); // Delay to demonstrate TOCTOU condition (race window) printThreads(t, 2Thread.sleep(1000); // At point 2, P2: the thread count changes as new threads are initiated int n = t.enumerate(ta);printActiveCount(2); // Incorrectly uses the (now stale) thread count obtained at pointP1 1 printEnumeratedThreadsint n = tg.enumerate(ta, n); // Silently ignores printing newly initiated threads } } class HandleRequest implements Runnable {printEnumeratedThreads(ta, n); public void run() { System.out.println("Active Threads in Thread Group " + Thread.currentThread().getThreadGroup().getName() + " (Handler thread invoked this): " + " " + Thread.activeCount()); // (between P1 and P2) while(true) {} // InfiniteThis loopcode todestroys keepthe threadsthread activegroup forif demonstration it does } } {code} There is a Time of Check-Time of Use (TOCTOU) vulnerability in this implementation because obtaining the count and enumerating the list do not constitute an atomic operation. If new requests come in during the time interval between calling {{activeCount()}} and {{enumerate()}} in the {{main()}} method, the total number of threads in the group will increase but the enumerated list {{ta}} will contain only the initial number, that is two thread references ({{main}} and {{t}}). Consequently, the program operates on stale data instead of taking into account the newly started threads in the thread group {{Chief}}. Different runs of the program produce different values of the number of threads in the thread group {{Chief}} because of the race conditions and demonstrate how a few incoming requests can get completely ignored. Any subsequent use of the {{ta}} array may lead to undesirable object retention. h2. Compliant Solution To be compliant, avoid using the {{ThreadGroup}} class. Before Java 5.0, this class had to be extended as there was no other way to control the {{UncaughtExceptionHandler}}. The application provided handler {{UncaughtExceptionHandler}} comes into the picture when a thread exits because of an uncaught exception. In recent versions, the {{UncaughtExceptionHandler}} is maintained on a per-thread basis using an interface enclosed by the {{Thread}} class, leaving little to no functionality for the {{ThreadGroup}} class. \[[Goetz 06|AA. Java References#Goetz 06]\] h2. Risk Assessment Using the {{ThreadGroup}} APIs may result in race conditions, memory leaks and inconsistent object state. || Rule || Severity || Likelihood || Remediation Cost || Priority || Level || | CON17- J | low | probable | low | {color:#cc9900}{*}P6{*}{color} | {color:#cc9900}{*}L2{*}{color} | h3. Automated Detection TODO h3. Related Vulnerabilities Search for vulnerabilities resulting from the violation of this rule on the [CERT website|https://www.kb.cert.org/vulnotes/bymetric?searchview&query=FIELD+KEYWORDS+contains+CON01-J]. h2. References \[[API 06|AA. Java References#API 06]\] Methods {{activeCount}} and {{enumerate}}, Classes ThreadGroup and Thread \[[JavaThreads 04|AA. Java References#JavaThreads 04]\] 13.1 ThreadGroups \[[Bloch 01|AA. Java References#Bloch 01]\] Item 53: Avoid thread groups \[[Goetz 06|AA. Java References#Goetz 06]\] 7.3.1. Uncaught Exception Handlers \[[JPL 06|AA. Java References#JPL 06]\] 23.3.3. Shutdown Strategies \[[SDN 06|AA. Java References#SDN 06]\] Bug ID: 4089701 and 4229558 ---- [!The CERT Sun Microsystems Secure Coding Standard for Java^button_arrow_left.png!|CON16-J. Do not expect sleep() and yield() methods to have any synchronization semantics] [!The CERT Sun Microsystems Secure Coding Standard for Java^button_arrow_up.png!|11. Concurrency (CON)] [!The CERT Sun Microsystems Secure Coding Standard for Java^button_arrow_right.png!|CON18-J. Always invoke wait() and await() methods inside a loop] // not have any live threads for (Thread thr : ta) { thr.interrupt(); while(thr.isAlive()); } tg.destroy(); } } |
This implementation contains a time-of-check, time-of-use (TOCTOU) vulnerability because it obtains the count and enumerates the list without ensuring atomicity. If one or more new requests were to occur after the call to activeCount()
and before the call to enumerate()
in the main()
method, the total number of threads in the group would increase, but the enumerated list ta
would contain only the initial number, that is, two thread references: main
and controller
. Consequently, the program would fail to account for the newly started threads in the Chief
thread group.
Any subsequent use of the ta
array would be insecure. For example, calling the destroy()
method to destroy the thread group and its subgroups would not work as expected. The precondition to calling destroy()
is that the thread group must be empty with no executing threads. The code attempts to comply with the precondition by interrupting every thread in the thread group. However, the thread group would not be empty when the destroy()
method was called, causing a java.lang.IllegalThreadStateException
to be thrown.
Compliant Solution
This compliant solution uses a fixed thread pool rather than a ThreadGroup
to group its three tasks. The java.util.concurrent.ExecutorService
interface provides methods to manage the thread pool. Although the interface lacks methods for finding the number of actively executing threads or for enumerating the threads, the logical grouping can help control the behavior of the group as a whole. For instance, invoking the shutdownPool()
method terminates all threads belonging to a particular thread pool.
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public final class NetworkHandler {
private final ExecutorService executor;
NetworkHandler(int poolSize) {
this.executor = Executors.newFixedThreadPool(poolSize);
}
public void startThreads() {
for (int i = 0; i < 3; i++) {
executor.execute(new HandleRequest());
}
}
public void shutdownPool() {
executor.shutdown();
}
public static void main(String[] args) {
NetworkHandler nh = new NetworkHandler(3);
nh.startThreads();
nh.shutdownPool();
}
}
|
Before Java SE 5.0, applications that needed to catch an uncaught exception in a separate thread had to extend the ThreadGroup
class because this was the only direct approach to provide the required functionality. Specifically, an application's UncaughtExceptionHandler
could only be controlled by subclassing ThreadGroup
. In more recent versions of Java, UncaughtExceptionHandler
is maintained on a per-thread basis using an interface enclosed by the Thread
class. Consequently, the ThreadGroup
class provides little unique functionality [Goetz 2006], [Bloch 2008].
Refer to TPS03-J. Ensure that tasks executing in a thread pool do not fail silently for more information on using uncaught exception handlers in thread pools.
Risk Assessment
Use of the ThreadGroup
APIs may result in race conditions, memory leaks, and inconsistent object state.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
THI01-J | Low | Probable | Medium | P4 | L3 |
Automated Detection
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
Parasoft Jtest |
| CERT.THI01.AUTG | Do not use variables of the unsafe type 'java.lang.ThreadGroup' | ||||||
SonarQube |
| S3014 | "ThreadGroup" should not be used |
Bibliography
[API 2006] | Class |
Item 53, "Avoid Thread Groups" | |
Item 73, "Avoid Thread Groups" | |
Section 7.3.1, "Uncaught Exception Handlers" | |
Section 13.1, " | |
[Java Tutorials] | |
[JPL 2006] | Section 23.3.3, "Shutdown Strategies" |
[SDN 2006] | Bug ID 4089701 |
...