Wiki Markup
Client-side locking entails guarding client code that uses some object X with the lock X uses to guard its own state. In order to use client-side locking, you must know what lock X uses.
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While client-side locking is acceptable if when the thread-safe class commits to and clearly documents its locking strategy and clearly documents it, Goetz and colleagues caution against its misuse \[ [Goetz 2006|AA. Bibliography#Goetz 06]\]:
If extending a class to add another atomic operation is fragile because it distributes the locking code for a class over multiple classes in an object hierarchy, client-side locking is even more fragile because it entails putting locking code for class C into classes that are totally unrelated to C. Exercise care when using client-side locking on classes that do not commit to their locking strategy.
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The documentation of a class that supports client-side locking should explicitly state its applicability. For example, the class {{java.util.concurrent.ConcurrentHashMap<K,V>}} should not be used for client-side locking because its documentation states that \[ [API 2006|AA. Bibliography#API 06]\]2014] states that
... even though all operations are thread-safe, retrieval operations do not entail locking, and there is not any support for locking the entire table in a way that prevents all access. This class is fully interoperable with
Hashtablein programs that rely on its thread safety but not on its synchronization details.
Wiki Markup synchronizedList()}} wrapper method of {{java.util.Collections}} class states \[ [API 2006|AA. Bibliography#API 06]\] 2014] states:
In order to guarantee serial access, it is critical that all access to the backing list is accomplished through the returned list. It is imperative that the user manually synchronize on the returned list when iterating over it. Failure to follow this advice may result in non-deterministic behavior.
When the backing list is inaccessible to an untrusted client, note that this advice is consistent with guideline LCK04-J. Do not synchronize on a collection view if the backing collection is accessible.
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This noncompliant code example uses a thread-safe Book class that cannot be refactored. Refactoring might be impossible, for example, if when the source code is not available unavailable for review or if when the class is part of a general library that cannot be extended.
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final class Book { // Could change its locking policy in the future // to use private final locks private final String title; private Calendar dateIssued; private Calendar dateDue; Book(String title) { this.title = title; } public synchronized void issue(int days) { dateIssued = Calendar.getInstance(); dateDue = Calendar.getInstance(); dateDue.add(dateIssued.DATE, days); } public synchronized Calendar getDueDate() { return dateDue; } } |
This class does not fails to commit to its locking strategy (that is, it reserves the right to change its locking strategy without notice). Furthermore, it does not fails to document that callers can safely use client-side locking. The client class BookWrapper client class uses client-side locking in the renew() method by synchronizing on a Book instance.
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// Client
public class BookWrapper {
private final Book book;
BookWrapper(Book book) {
this.book = book;
}
public void issue(int days) {
book.issue(days);
}
public Calendar getDueDate() {
return book.getDueDate();
}
public void renew() {
synchronized(book) {
if (book.getDueDate().before(Calendar.getInstance())) {
throw new IllegalStateException("Book overdue");
} else {
book.issue(14); // Issue book for 14 days
}
}
}
}
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If the Book class changes were to change its synchronization policy in the future, the BookWrapper class's locking strategy might silently break. For instance, the Bookwrapper BookWrapper class's locking strategy breaks would break if Book is were modified to use a private final lock object, as recommended by guideline LCK00-J. Use private final lock objects to synchronize classes that may interact with untrusted code. The BookWrapper class's locking strategy breaks This is because threads that call BookWrapper.getDueDate() may would perform operations on the thread-safe Book using its new locking policy. However, threads that call the renew() method will would always synchronize on the intrinsic lock of the Book instance. Consequently, the implementation will would use two different locks.
Compliant Solution (Private Final Lock Object)
This compliant solution uses a private final lock object and synchronizes the methods of the BookWrapper class using this lock.:
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public final class BookWrapper {
private final Book book;
private final Object lock = new Object();
BookWrapper(Book book) {
this.book = book;
}
public void issue(int days) {
synchronized(lock) {
book.issue(days);
}
}
public Calendar getDueDate() {
synchronized(lock) {
return book.getDueDate();
}
}
public void renew() {
synchronized(lock) {
if (book.getDueDate().before(Calendar.getInstance())) {
throw new IllegalStateException("Book overdue");
} else {
book.issue(14); // Issue book for 14 days
}
}
}
}
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Noncompliant Code Example (Class Extension and Accessible Member Lock)
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Goetz and colleagues describe the fragility of class extension for adding functionality to to thread-safe classes \[ [Goetz 2006|AA. Bibliography#Goetz 06]\]:
Extension is more fragile than adding code directly to a class, because the implementation of the synchronization policy is now distributed over multiple, separately maintained source files. If the underlying class were to change its synchronization policy by choosing a different lock to guard its state variables, the subclass would subtly and silently break because it no longer used the right lock to control concurrent access to the base class's state.
In this noncompliant code example, the PrintableIPAddressList class extends the thread-safe IPAddressList class. PrintableIPAddressList locks on IPAddressList.ips in the addAndPrintIPAddresses() method. This is another example of client-side locking because a subclass is using an object owned and locked by its superclass.
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// This class could change its locking policy in the future, // for example, // if new non-atomic methods are added class IPAddressList { private final List<InetAddress> ips = Collections.synchronizedList(new ArrayList<InetAddress>()); public List<InetAddress> getList() { return ips; // No defensive copies required // as visibility is package-private visibility } public void addIPAddress(InetAddress address) { ips.add(address); } } class PrintableIPAddressList extends IPAddressList { public void addAndPrintIPAddresses(InetAddress address) { synchronized (getList()) { addIPAddress(address); InetAddress[] ia = (InetAddress[]) getList().toArray(new InetAddress[0]); // ... } } } |
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If the {{IPAddressList}} class is modified to use block synchronization on a private final lock object, as recommended by guideline [ class were modified to use block synchronization on a private final lock object, as recommended by LCK00-J. Use private final lock objects to synchronize classes that may interact with untrusted code], the {{PrintableIPAddressList}} subclass will silently subclass would silently break. Moreover, if a wrapper such as {{Collections.synchronizedList()}} is were used, it is would be difficult for a client to determine the type of the class being wrapped to extend it \ [[Goetz 2006|AA. Bibliography#Goetz 06]\].
Compliant Solution (Composition)
This compliant solution wraps an object of the IPAddressList class and provides synchronized accessors that can be used to manipulate the state of the object. Composition offers encapsulation benefits, usually with minimal overhead . Refer to guideline OBJ07(refer to OBJ02-J. Understand how a superclass can affect a subclassPreserve dependencies in subclasses when changing superclasses for more information on composition).
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// Class IPAddressList remains unchanged class PrintableIPAddressList { private final IPAddressList ips; public PrintableIPAddressList(IPAddressList list) { this.ips = list; } public synchronized void addIPAddress(InetAddress address) { ips.addIPAddress(address); } public synchronized void addAndPrintIPAddresses(InetAddress address) { addIPAddress(address); InetAddress[] ia = (InetAddress[]) ips.getList().toArray(new InetAddress[0]); // ... } } |
Wiki Markup PrintableIPAddressList}} class to use its own intrinsic lock independent of the underlying list class's lock. The underlying collection does not need to be thread-safe because the {{PrintableIPAddressList}} wrapper prevents direct access to its methods by publishing its own synchronized equivalents. This approach provides consistent locking even if the underlying class changes its locking policy in the future \[[Goetz 2006|AA. Bibliography#Goetz 06]\collection lacks a requirement for thread-safety because the PrintableIPAddressList wrapper prevents direct access to its methods by publishing its own synchronized equivalents. This approach provides consistent locking even when the underlying class changes its locking policy in the future [Goetz 2006].
Risk Assessment
Using client-side locking when the the thread-safe class does not fails to commit to its locking strategy can cause data inconsistencies and deadlock.
Guideline Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
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LCK11-J | low Low | probable Probable | medium Medium | P4 | L3 |
Automated Detection
TODO
Related Vulnerabilities
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Bibliography
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[API |
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2014] | Class Collections |
Section 8.2, "Synchronization and Collection Classes" | |
Section 4.4.1 |
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Locking |
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, "Composition" |
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[Lee |
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Compound |
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Operation" |
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LCK10-J. Do not use incorrect forms of the double-checked locking idiom 08. Locking (LCK) Thread APIs (THI)