...
A
...
common misconception is that shared references to immutable objects are immediately visible across multiple threads as soon as they are updated. For example, a developer can mistakenly believe that a class containing fields that refer only to immutable objects is itself immutable and consequently thread-safe.
Section 14.10.2, "Final Fields and Security," of Java Programming Language, Fourth Edition [JPL 2006] states:
The problem is that, while the shared object is immutable, the reference used to access the shared object is itself shared and often mutable. Consequently, a correctly synchronized program must synchronize access to that shared reference, but often programs do not do this, because programmers do not recognize the need to do it.
References to both immutable and mutable objects must be made visible to all the threads. Immutable objects can be shared safely among multiple threads. However, references to mutable objects can be made visible before the objects are fully constructed. TSM03-J. Do not publish partially initialized objects describes object construction and visibility issues specific to mutable objects.
Noncompliant Code Example
This noncompliant code example consists of the immutable Helper
class:
Code Block | ||
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| ||
error is to assume that shared references to immutable objects are made visible across multiple threads as soon as they are updated. For instance, a developer may incorrectly conceive that a class containing fields referring to only immutable objects, is immutable. However, this class is not even thread-safe. The Java⢠Programming Language, Fourth Edition \[[JPL 06|AA. Java References#JPL 06]\], "Section 14.10.2. Final Fields and Security" states: {quote} ... you can use {{final}} fields to define immutable objects. There is a common misconception that shared access to immutable objects does not require any synchronization because the state of the object never changes. This is a misconception in general because it relies on the assumption that a thread will be guaranteed to see the initialized state of the immutable object, and that need not be the case. The problem is that, while the shared object is immutable, the reference used to access the shared object is itself shared and often mutable. Consequently, a correctly synchronized program must synchronize access to that shared reference, but often programs do not do this, because programmers do not recognize the need to do it. For example, suppose one thread creates a {{String}} object and stores a reference to it in a {{static}} field. A second thread then uses that reference to access the string. There is no guarantee, based on what we've discussed so far, that the values written by the first thread when constructing the string will be seen by the second thread when it accesses the string. {quote} Immutable objects can be safely shared amongst multiple threads. However, mutable objects may not be fully constructed when their references are made visible. References to either kinds of objects must be made visible to all the threads. The guideline [CON26-J. Do not publish partially-constructed objects] focuses on object construction and visibility issues specific to mutable objects. h2. Noncompliant Code Example This noncompliant code example consists of an immutable class {{Helper}}: {code} // Immutable Helper public final class Helper { private final int n; public Helper(int n) { this.n = n; } // ... } {code} |
and
...
a
...
mutable Foo
class:
Code Block | ||
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| ||
final class {{Foo}}: {code:bgColor=#FFCCCC} class Foo { private Helper helper; public Helper getHelper() { return helper; } public void setHelper(int num) { helper = new Helper(num); } } {code} The {{Foo. |
The getHelper()
...
method
...
publishes
...
the
...
mutable
...
helper
field. Because the Helper
class is immutable, it cannot be changed after it is initialized.
Furthermore, because Helper
is immutable, it is always constructed properly before its reference is made visible, in compliance with TSM03-J. Do not publish partially initialized objects. Unfortunately, a separate thread could observe a stale reference in the helper
field of the Foo
class.
Compliant Solution (Synchronization)
This compliant solution synchronizes the methods of the Foo
class to ensure that no thread sees a stale Helper
reference:
Code Block | ||
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| ||
final }} field. {mc} I am changing the previous line because it talks about synchronization which is a CS {mc} As the {{Helper}} class is [immutable|BB. Definitions#immutable], it cannot be changed after it is initialized and is always properly constructed before its reference is made visible, in compliance with [CON26-J. Do not publish partially-constructed objects]. However, some thread can observe the {{helper}} field of class {{Foo}} to contain a stale reference. h2. Compliant Solution (synchronization) This compliant solution synchronizes the methods of class {{Foo}} to ensure that no thread sees a stale {{Helper}} reference. {code:bgColor=#CCCCFF} class Foo { private Helper helper; public synchronized Helper getHelper() { return helper; } public synchronized void setHelper(int num) { helper = new Helper(num); } } {code} |
The
...
immutable
...
Helper
...
class remains unchanged.
...
Compliant
...
Solution
...
(
...
volatile
...
)
...
References
...
to
...
immutable
...
member
...
objects
...
can
...
be
...
made
...
visible
...
by
...
declaring
...
them volatile:
Code Block | ||
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final {{volatile}} as described in [CON00-J. Ensure visibility of atomically accessed shared variables]. {code:bgColor=#CCCCFF} class Foo { private volatile Helper helper; public Helper getHelper() { return helper; } public void setHelper(int num) { helper = new Helper(num); } } {code} |
The
...
immutable
...
Helper
...
class remains unchanged.
Compliant Solution (java.util.concurrent
Utilities)
This compliant solution wraps the mutable reference to the immutable Helper
object within an AtomicReference
wrapper that can be updated atomically:
Code Block | ||
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| ||
final class Foo {
private final AtomicReference<Helper> helperRef =
new AtomicReference<Helper>();
public Helper getHelper() {
return helperRef.get();
}
public void setHelper(int num) {
helperRef.set(new Helper(num));
}
}
|
The immutable Helper
class remains unchanged.
Risk Assessment
The incorrect assumption that classes that contain only references to immutable objects are themselves immutable can cause serious thread-safety issues.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
VNA01-J | Low | Probable | Medium | P4 | L3 |
Automated Detection
Some static analysis tools are capable of detecting violations of this rule.
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
ThreadSafe |
| CCE_SL_INCONSISTENT | Implemented | ||||||
SonarQube |
| S2886 | Getters and setters should be synchronized in pairs |
Bibliography
Issue Tracking
Tasklist | ||||
---|---|---|---|---|
| ||||
||Completed||Priority||Locked||CreatedDate||CompletedDate||Assignee||Name||
|F|M|F|1270826173609| |dmohindr|"Unfortunately, a separate thread -could- *can* observe a stale reference in the helper field of the Foo class."|
|T|M|F|1270826698362|1271441478121|svoboda|"This compliant solution synchronizes the methods of *class* Foo -class- " (it sounds strange with class occuring after Foo)|
|
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