Java supports the use of various types of literals, such as integers (5, 2), floating point numbers (2.5, 6.022e+23), characters ('a', '\n'), booleans ('true', 'false'), and strings ("Hello\n"). Extensive use of literals within a program can lead to two problems: first, the meaning of the literal is often obscured or unclear from the context (magic numbers); second, changing a frequently-used literal requires both searching the entire program source for occurrences of that literal, and also distinguishing the uses that must be modified from those that should remain unmodified.
Avoid these problems by declaring meaningfully-named constants class variables, setting their values to the desired literals, and referencing the constants in place of the literals throughout the program. This approach allows the use of a name that clearly indicates the meaning or intended use of the literal. Further, should the constant require modification, the change is limited to the declaration; searching the code is unnecessary.
final
The final
keyword in Java is used to declare constants. Its effect is to render the affected non-composite variable immutable. Attempts to change the value of a final
-qualified variable after it has been initialized result in a compile-time error. Because constants cannot be changed, it is desirable to define only one instance of them for the class; consequently, constants should also be declared with the static
modifier. (See guideline DCL04-J. Declare mathematical constants as static and final.)
The following code fragment demonstrates the use of static
and final
to create a constant:
private static final int SIZE = 25;
This code snippet declares the value SIZE
to be type int
and value 25. This constant can subsequently be used wherever the value 25 is needed.
Although final
is most often safe for creating compile time immutable constants, its use has a few caveats when dealing with composite objects (mutable data in particular). See guideline OBJ01-J. Do not assume that declaring a reference to be final causes the referenced object to be immutable for more details.
Noncompliant Code Example
This noncompliant code example calculates approximate dimensions of a sphere, given its radius.
double area(double radius) { return 12.56 * radius*radius; } double volume(double radius) { return 4.19 * radius * radius * radius; } double greatCircleCircumference(double radius) { return 6.28 * radius; }
The methods use the seemingly-random literals 12.56, 4.19, and 6.28 to represent various scaling factors used to calculate these dimensions. Someone reading this code would have little idea about how they were generated or what they mean, and would, consequently, be unable to understand the function of this code.
Noncompliant Code Example
This noncompliant code attempts to avoid the above issues by explicitly calculating the required constants.
double area(double radius) { return 4.0 * 3.14 * radius * radius; } double volume(double radius) { return 4.0/3.0 * 3.14 * radius * radius * radius; } double greatCircleCircumference(double radius) { return 2 * 3.14 * radius; }
The code uses the literal 3.14 to represent the value pi
. Although this removes some of the ambiguity from the literals, it complicates code maintenance. If the programmer were to decide that a more precise value of pi
is desired, all occurrences of 3.14 in the code would have to be found and replaced.
Compliant Solution
In this compliant solution, a constant PI
is first declared and initialized to 3.14. Thereafter, it is referenced in the code whenever the value of pi
is needed.
private static final int PI = 3.14; double area(double radius) { return 4.0 * PI * radius * radius; } double volume(double radius) { return 4.0/3.0 * PI * radius * radius * radius; } double greatCircleCircumference(double radius) { return 2 * PI * radius; }
This reduces clutter and promotes maintainability. If a more precise value of pi
is required, the programmer can simply redefine the constant.
Compliant Solution (Predefined Constants)
The class java.lang.Math
defines a large set of numeric constants, such as PI
and the exponential constant E
. Prefer the use of predefined constants when they are available.
double area(double radius) { return 4.0 * Math.PI * radius * radius; } double volume(double radius) { return 4.0/3.0 * Math.PI * radius * radius * radius; } double greatCircleCircumference(double radius) { return 2 * Math.PI * radius; }
Exceptions
DCL02-EX1: The use of symbolic constants should be restricted to cases where they improve the readability and maintainability of the code. Using them when the intent of the literal is obvious, or where the literal is not likely to change, can impair code readability. In the preceding compliant solution, the values 4.0 and 3.0 in the volume calculation are clearly scaling factors used to calculate the circle volume and are not subject to change (unlike pi
), so they can be represented exactly; there is no reason to change them to increase precision. Hence, replacing them with symbolic constants is inappropriate.
Risk Assessment
Using numeric literals makes code more difficult to read, understand, and edit.
Guideline |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
---|---|---|---|---|---|
DCL02-J |
low |
unlikely |
high |
P1 |
L3 |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this guideline on the CERT website.
Related Guidelines
C++ Secure Coding Standard: DCL06-CPP. Use meaningful symbolic constants to represent literal values in program logic
C Secure Coding Standard: DCL06-C. Use meaningful symbolic constants to represent literal values
Bibliography
[[API 2006]]
[[Core Java 2004]]
DCL01-J. Do not declare more than one variable per declaration 03. Declarations and Initialization (DCL) DCL03-J. Properly encode relationships in constant definitions