Method chaining is a convenience mechanism that allows multiple method invocations on the same object to occur in a single statement. Classes that support method chaining provide several setter methods that return the this reference.
Method chaining should not be used in a multithreaded environment because chained invocations of a set of methods are non-atomic and, consequently, noncompliant with CON07-J. Do not assume that a group of calls to independently atomic methods is atomic.
Noncompliant Code Example
Method chaining is useful for building an object and setting its optional fields. However, in a multithreaded environment, a thread may observe a shared field to contain inconsistent values. This noncompliant code example shows the Javabeans pattern which is not safe for multithreaded use.
final class USCurrency {
// Change requested, denomination (optional fields)
private int quarters = 0;
private int dimes = 0;
private int nickels = 0;
private int pennies = 0;
public USCurrency() {}
// Setter methods
public USCurrency setQuarters(int quantity) {
quarters = quantity;
return this;
}
public USCurrency setDimes(int quantity) {
dimes = quantity;
return this;
}
public USCurrency setNickels(int quantity) {
nickels = quantity;
return this;
}
public USCurrency setPennies(int quantity) {
pennies = quantity;
return this;
}
}
// Client code:
private final USCurrency currency = new USCurrency();
// ...
new Thread(new Runnable() {
@Override public void run() {
currency.setQuarters(1).setDimes(1);
}
}).start();
new Thread(new Runnable() {
@Override public void run() {
currency.setQuarters(2).setDimes(2);
}
}).start();
The Javabeans pattern uses a no-argument constructor and a series of parallel setter methods to build an object. This pattern is not thread-safe and can lead to inconsistent object state. In this example, a client that constructs a USCurrency object and starts two threads as shown may find the object to contain two quarters and one dime or one quarter and two dimes, contrary to what it expects.
Compliant Solution
This compliant solution uses the variant of the Builder pattern [[Gamma 95]] suggested by Bloch [[Bloch 08]] to ensure thread safety and atomicity of object creation.
final class USCurrency {
private final int quarters;
private final int dimes;
private final int nickels;
private final int pennies;
public USCurrency(Builder builder) {
this.quarters = builder.quarters;
this.dimes = builder.dimes;
this.nickels = builder.nickels;
this.pennies = builder.pennies;
}
// Static class member
public static class Builder {
private int quarters = 0;
private int dimes = 0;
private int nickels = 0;
private int pennies = 0;
private Builder() {}
// Setter methods
public Builder setQuarters(int quantity) {
this.quarters = quantity;
return this;
}
public Builder setDimes(int quantity) {
this.dimes = quantity;
return this;
}
public Builder setNickels(int quantity) {
this.nickels = quantity;
return this;
}
public Builder setPennies(int quantity) {
this.pennies = quantity;
return this;
}
public USCurrency build() {
return new USCurrency(this);
}
public static Builder newInstance() {
return new Builder();
}
}
}
// Client code:
private volatile USCurrency currency;
// ...
new Thread(new Runnable() {
@Override public void run() {
currency = USCurrency.Builder.newInstance().setQuarters(1).setDimes(1).build();
}
}).start();
new Thread(new Runnable() {
@Override public void run() {
currency = USCurrency.Builder.newInstance().setQuarters(2).setDimes(2).build();
}
}).start();
The Builder.newInstance() factory method is called with the required arguments (if any) to obtain a Builder object. The optional parameters are set using the setter methods of the builder. The object construction concludes with the invocation of the build() method. This also makes the class Currency immutable, and consequently, thread-safe.
Note that the currency field cannot be declared as final because it is set to a new immutable object from the threads. It is declared as volatile in compliance with CON09-J. Ensure visibility of shared references to immutable objects.
If input needs to be validated, ensure that the values are defensively copied prior to the validation (see FIO00-J. Defensively copy mutable inputs and mutable internal components for more information). The builder class does not violate SCP03-J. Do not expose sensitive private members of the outer class from within a nested class because it maintains a copy of the variables defined in the scope of the containing class. These take precedence and as a result, do not break encapsulation.
Exceptions
EX1: A class may use method chaining in a multithreaded environment if it sufficiently documents this fact. Client code must externally use some locking to ensure that the method calls are thread-safe.
Risk Assessment
Using method chaining in multithreaded environments without performing external locking can lead to non-deterministic behavior.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
|---|---|---|---|---|---|
CON30- 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]]
[[Bloch 08]] Item 2: "Consider a builder when faced with many constructor parameters"
FIO36-J. Do not create multiple buffered wrappers on an InputStream 09. Input Output (FIO) 09. Input Output (FIO)