Instead of initializing a member object using a constructor, lazy initialization can be used to defer the construction of the member object until an instance is actually required. Lazy initialization also helps in breaking harmful circularities in class and instance initialization and performing other optimizations [[Bloch 05]].
A class or an instance method is used for lazy initialization, depending on whether the member object is static
or not. The method checks whether the instance has already been created and if not, creates it. If the instance already exists, it simply returns it:
// Correct single threaded version using lazy initialization final class Foo { private Helper helper = null; public Helper getHelper() { if (helper == null) { helper = new Helper(); } return helper; } // ... }
In a multithreaded application, initialization must be synchronized so that multiple threads do not create extraneous instances of the member object:
// Correct multithreaded version using synchronization final class Foo { private Helper helper = null; public synchronized Helper getHelper() { if (helper == null) { helper = new Helper(); } return helper; } // ... }
The double-checked locking idiom improves performance by limiting synchronization to the rare case of new instance creation and forgoing it during the common case of retrieving an already created instance.
Noncompliant Code Example
The double-checked locking pattern uses block synchronization instead of method synchronization; installing an additional null
check before attempting synchronization. This noncompliant code example uses the incorrect form of the double checked locking idiom.
// "Double-Checked Locking" idiom final class Foo { private Helper helper = null; public Helper getHelper() { if (helper == null) { synchronized (this) { if (helper == null) { helper = new Helper(); } } } return helper; } // Other methods and members... }
According to the Java Memory Model (discussion reference) [[Pugh 04]]:
... writes that initialize the
Helper
object and the write to thehelper
field can be done or perceived out of order. As a result, a thread which invokesgetHelper()
could see a non-null reference to ahelper
object, but see the default values for fields of thehelper
object, rather than the values set in the constructor.Even if the compiler does not reorder those writes, on a multiprocessor the processor or the memory system may reorder those writes, as perceived by a thread running on another processor.
See also CON26-J. Do not publish partially initialized objects.
Compliant Solution (Volatile)
This compliant solution declares the Helper
object volatile.
// Works with acquire/release semantics for volatile // Broken under JDK 1.4 and earlier final class Foo { private volatile Helper helper = null; public Helper getHelper() { if (helper == null) { synchronized (this) { if (helper == null) { helper = new Helper(); // If the helper is null, create a new instance } } } return helper; // If helper is non-null, return its instance } }
If a thread initializes the Helper
object, a [happens-before relationship] is established between this thread and another that retrieves and returns the instance. [[Pugh 04]] and [[Manson 04]]
Compliant Solution (Static Initialization)
This compliant solution initializes the helper
field in the declaration of the static variable [[Manson 06]].
final class Foo { private static final Helper helper = new Helper(); public static Helper getHelper() { return helper; } }
Variables that are declared static and initialized at declaration, or from a static initializer, are guaranteed to be fully constructed before being made visible to other threads.
Compliant Solution (Initialize-on-demand Holder Class Idiom)
This compliant solution uses the initialize-on-demand holder class idiom that implicitly incorporates lazy initialization by declaring a static variable within a static inner class Holder
.
final class Foo { // Lazy initialization private static class Holder { static Helper helper = new Helper(); } public static Helper getInstance() { return Holder.helper; } }
Initialization of the static helper
field is deferred until the getInstance()
method is called. This idiom is a better choice than the double checked locking idiom for lazily initializing static fields [[Bloch 08]]. However, this idiom cannot be used to lazily initialize instance fields [[Bloch 01]].
Compliant Solution (ThreadLocal
Storage)
This compliant solution (originally suggested by Alexander Terekhov [[Pugh 04]]) uses a ThreadLocal
object to lazily create a Helper
instance.
class Foo { private final ThreadLocal<Foo> perThreadInstance = new ThreadLocal<Foo>(); private Helper helper = null; public Helper getHelper() { if (perThreadInstance.get() == null) { createHelper(); } return helper; } private final synchronized void createHelper() { if (helper == null) { helper = new Helper(); } // Any non-null value can be used as an argument to set() perThreadInstance.set(this); } }
Exceptions
CON22-EX1: The noncompliant form of the double-checked locking idiom can be used for for 32-bit primitive values (for example, int
or float
) [[Pugh 04]]. Note that it does not work for long
or double
because unsynchronized reads/writes of 64-bit primitives are not guaranteed to be atomic (see [CON25-J. Ensure atomicity when reading and writing 64-bit values].)
Risk Assessment
Using incorrect forms of the double checked locking idiom can lead to synchronization problems.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
---|---|---|---|---|---|
CON22- J |
low |
probable |
medium |
P4 |
L3 |
Automated Detection
TODO
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
References
[[API 06]]
[[JLS 05]] Section 12.4, "Initialization of Classes and Interfaces"
[[Pugh 04]]
[[Bloch 01]] Item 48: "Synchronize access to shared mutable data"
[[Bloch 08]] Item 71: "Use lazy initialization judiciously"
[[MITRE 09]] CWE ID 609 "Double-Checked Locking"
CON21-J. Use thread pools to enable graceful degradation of service during traffic bursts 11. Concurrency (CON) MSC16-J. Address the shortcomings of the Singleton design pattern