According to Sun's Secure Coding Guidelines document [[SCG 07]]:
The (Java) language is type-safe, and the runtime provides automatic memory management and range-checking on arrays. These features also make Java programs immune to the stack-smashing and buffer overflow attacks possible in the C and C++ programming languages, and that have been described as the single most pernicious problem in computer security today.
While this statement is true, arithmetic operations in the Java platform require as much caution as in C and C++. Integer operations can result in overflow because Java does not provide any indication of overflow conditions and silently wraps. While integer overflows in vulnerable C and C++ programs may result in execution of arbitrary code, in Java, wrapped values typically result in incorrect computations and unanticipated outcomes.
According to the Java Language Specification [[JLS 05]], section 4.2.2 Integer Operations:
The built-in integer operators do not indicate overflow or underflow in any way. Integer operators can throw a
NullPointerException
if unboxing conversion of anull
reference is required. Other than that, the only integer operators that can throw an exception are the integer divide operator/
and the integer remainder operator%
, which throw anArithmeticException
if the right-hand operand is zero, and the increment and decrement operators ++ and -- which can throw anOutOfMemoryError
if boxing conversion is required and there is not sufficient memory available to perform the conversion.
The integral types in Java are byte
, short
, int
, and long
, whose values are 8-bit, 16-bit, 32-bit and 64-bit signed twoâs-complement integers, respectively, and char
, whose values are 16-bit unsigned integers representing UTF-16 code units.
According to the Java Language Specification [[JLS 05]], section 4.2.1 "Integral Types and Values", the values of the integral types are integers in the following ranges:
- For byte, from â“128 to 127, inclusive
- For short, from â“32768 to 32767, inclusive
- For int, from â“2147483648 to 2147483647, inclusive
- For long, from â“9223372036854775808 to 9223372036854775807, inclusive
- For char, from '\u0000' to '\uffff' inclusive, that is, from 0 to 65535
The table shown below enlists the operators that can lead to overflows:
Operator |
Overflow |
|
Operator |
Overflow |
|
Operator |
Overflow |
|
Operator |
Overflow |
---|---|---|---|---|---|---|---|---|---|---|
yes |
|
yes |
|
no |
|
|
no |
|||
yes |
|
yes |
|
|
no |
|
|
no |
||
yes |
|
yes |
|
|
no |
|
|
no |
||
yes |
|
no |
|
\ |
no |
|
|
no |
||
no |
|
no |
|
|
no |
|
|
no |
||
|
yes |
|
|
no |
|
|
no |
|
|
no |
|
yes |
|
|
no |
|
|
no |
|
|
no |
|
no |
|
|
no |
|
un |
no |
|
|| |
no |
yes |
|
|
no |
|
yes |
|
|
no |
Failing to account for integer overflow has resulted in failures in real systems, for instance, when implementing the compareTo()
method. The compareTo()
method does not care about the magnitude of the operands but only about the sign. Consequently, an optimization is to simply subtract the operands and return the result. For nonpositive operands, this can result in integer overflow and violation of the compareTo()
contract. [[Bloch 08, item 12]]
Addition
Addition (as with all arithmetic operations) in Java is performed on signed numbers only as unsigned numbers are unsupported. One exception is the unsigned char
type. Performing arithmetic operations that use operands of type char
is strongly discouraged.
Noncompliant Code Example
In this noncompliant code example, the result of the addition can overflow.
public int do_operation(int a, int b){ // May result in overflow int temp = a + b; return temp; }
If the result of the addition is greater than the maximum value or less than the minimum value that can be represented as an int
, then the variable temp
will contain an erroneous result. This does not apply to shorter types such as byte
and short
because the operands are promoted to an int
before the operation is carried out in cases where the value may not be representable. The compiler disallows storing the result of such an operation in a variable of type shorter than an int
.
Compliant Solution (Bounds Checking)
Explicitly check the range of each arithmetic operation and throw an ArithmeticException
on overflow. When performing operations on values of type int
, the arithmetic can be performed using variables of type long
. For performing arithmetic operations on numbers of type long
, the BigInteger
Class must be used.
Because a variable of the long
type is guaranteed to hold the result of an addition, subtraction or multiplication of values of type int
, the result can be assigned to such a variable, and if the result is in the integer range, we can simply downcast it to a value of type int
.
Compliant Solution (Use long
and Downcast)
This compliant solution uses a variable of type long
to store the result of the addition and proceeds to range check its value.
If the value cannot be represented in a variable of type int
, it throws an ArithmeticException
. Otherwise, it down casts the result to a value of type int
.
public int do_operation(int a, int b) throws ArithmeticException { long temp = (long)a + (long)b; if (temp > Integer.MAX_VALUE || temp < Integer.MIN_VALUE) { throw new ArithmeticException("Out of range"); } return (int)temp; // Value within range; can perform the addition }
Compliant Solution (Bounds Checking)
This compliant solution range checks the operand values to ensure that the result does not overflow.
public int do_operation(int a, int b) throws ArithmeticException { if( b > 0 ? a > Integer.MAX_VALUE - b : a < Integer.MIN_VALUE - b ) { throw new ArithmeticException("Not in range"); } return a + b; // Value within range so addition can be performed }
Compliant Solution (Use BigInteger Class)
This compliant solution uses the BigInteger
class as a wrapper to test for the overflow.
public boolean overflow(long a, long b) { BigInteger ba = new BigInteger(String.valueOf(a)); BigInteger bb = new BigInteger(String.valueOf(b)); BigInteger br = ba.add(bb); return (br.compareTo(BigInteger.valueOf(Long.MAX_VALUE)) == 1 || br.compareTo(BigInteger.valueOf(Long.MIN_VALUE)) == -1); } public long do_operation(long a, long b) throws ArithmeticException { if(overflow(a,b)) { throw new ArithmeticException("Not in range"); } // Within range; safely perform the addition return a + b; }
With use of the BigInteger
class, integer overflows are eliminated. However, due to increased performance costs, it should be used only when other methods are not appropriate.
Subtraction
Care must be taken while performing the subtraction operation as well because overflows (or underflows) are possible.
Noncompliant Code Example
In this noncompliant code example, the subtraction operation may overflow negatively when a
is a negative integer and b
is a large positive integer such that their sum is not representable as a value of type int
. It can also overflow when a
is positive and b
is negative and their sum is not representable as a value of type int
.
public int do_operation(int a, int b) { int temp = a - b; // Could result in overflow return temp; }
Compliant Solution (Use Long)
This compliant solution suggests explicit range checking before performing the subtraction.
public int do_operation(int a,int b) { long temp = (long)a - (long)b; if(temp < Integer.MIN_VALUE || temp > Integer.MAX_VALUE) { throw new ArithmeticException("Not in range"); } return (int) temp; }
Compliant Solution (Bounds Checking)
This compliant solution uses range checking to ensure that the result will not overflow.
public int do_operation(int a, int b) throws ArithmeticException { if(b > 0 ? a < Integer.MIN_VALUE + b : a > Integer.MAX_VALUE + b ) { throw new ArithmeticException("Not in range"); } return a - b; // Value within range; can perform the addition }
Compliant Solution (Use BigInteger Class)
The BigInteger
class can be used as a overflow-test wrapper as shown in this compliant solution.
public boolean underflow(long a, long b) { BigInteger ba = new BigInteger(String.valueOf(a)); BigInteger bb = new BigInteger(String.valueOf(b)); BigInteger br = ba.subtract(bb); return (br.compareTo(BigInteger.valueOf(Long.MAX_VALUE)) == 1 || br.compareTo(BigInteger.valueOf(Long.MIN_VALUE)) == -1); } public long do_operation(long a, long b) throws ArithmeticException { if(underflow(a,b)) { throw new ArithmeticException("Not in range"); } // Within range; safely perform the subtraction return a - b; }
Multiplication
This noncompliant code example can result in a signed integer overflow during the multiplication of the signed operands a
and b
. If this behavior is unanticipated, the resulting value may lead to undefined behavior.
Noncompliant Code Example
int a, b, result //do stuff result = a * b; // May result in overflow
Compliant Solution
Because the size of the type long
(64 bits) is twice the size of the type int
(32 bits), the multiplication should be performed using a variable of type long
. If the product is in the range of the int
type, it can be safely downcast to a value of type int
.
int a, b, result; long temp = (long) a * (long)b; if(temp > Integer.MAX_VALUE || temp < Integer.MIN_VALUE) { throw new ArithmeticException("Not in range"); // Overflow } result = (int) temp; // Value within range, safe to downcast
Division
Although Java throws a java.lang.ArithmeticException
for division by zero, the same issue as with C/C++ manifests, while dividing the Integer.MIN_VALUE
by -1. It produces Integer.MIN_VALUE
unexpectedly (as the result is -(Integer.MIN_VALUE) = Integer.MAX_VALUE + 1
)).
Noncompliant Code Example
This noncompliant code example divides a
and b
without checking the range of the result.
int a; int b; int result; result = a/b;
Compliant Solution
This compliant solution handles the special case of Integer.MIN_VALUE
and -1
being used as the dividend and divisor, respectively.
if(a == Integer.MIN_VALUE && b == -1) { throw new ArithmeticException("Not in range"); // May be Integer.MIN_VALUE and -1 } result = a/b; // Safe operation
Remainder Operator
The remainder operator in Java has the following behavior for corner cases:
- If the modulo of
Integer.MIN_VALUE
with -1 is taken the result is always 0.
- If the right-hand operand is zero, then the integer remainder operator % will throw an
ArithmeticException
.
- The sign of the remainder is always the same as that of the dividend. For example,
-3
%-2
results in the value-1
. This behavior can sometimes be deceptive.
Refer to INT02-J. Do not assume a positive remainder when using the remainder operator for more details.
Unary Negation
If Integer.MIN_VALUE
is negated, the same value Integer.MIN_VALUE
is obtained. Range checking is important in this case as well.
Noncompliant Code Example
This noncompliant code example tries to negate the result without checking whether it is Integer.MIN_VALUE
.
int temp = -result;
Compliant Solution
This compliant solution explicitly checks whether the input is Integer.MIN_VALUE
and throws an exception if it is; otherwise, it negates the result.
if(result == Integer.MIN_VALUE) { throw new ArithmeticException("Not in range"); } temp = -result;
Absolute Value
A related pitfall is the use of the Math.abs()
method that takes a parameter of type int
and returns its absolute value. Because of the asymmetry between the representation of negative and positive integer values (Integer.MAX_VALUE
is 2147483647 and Integer.MIN_VALUE
is -2147483648, which means there is one more negative integer than positive integers), there is no equivalent positive value (+2147483648) for Integer.MIN_VALUE
.
Shifting
The shift operation in Java has the following properties:
- The right shift is an arithmetic shift
- The types
boolean, float and double
cannot use the bit shifting operators.
- If the value to be shifted is of type
int
, only the five lowest-order bits of the right-hand operand are used as the shift distance. That is, the shift distance is the value of the right-hand operand masked by 31 (0x1F). This results in a value modulo 31, inclusive.
When the value to be shifted (left-operand) is of type
long
, only the last 6 bits of the right-hand operand are used to perform the shift. The shift distance is the value of the right-hand operand masked by 63 (0x3D) [[JLS 03]], i.e., it is always between 0 and 63. (If the shift value is greater than 64, then the shift isvalue % 64
.)
Refer to INT05-J. Use shift operators correctly for further details about the behavior of the shift operators.
Noncompliant Code Example
This noncompliant code example attempts to shift the value i
of type int
until, after 32 iterations, the value becomes 0. Unfortunately, this loop never terminates because an attempt to shift a value of type int
by 32 bits results in the original value rather than the value 0. [[Bloch 05]]
int i = 0; while ((-1 << i) != 0) i++;
Compliant Solution
This compliant solution initially sets the value val
to -1 and repeatedly shifts the value by one place on each successive iteration.
for (int val = -1; val != 0; val <<= 1) { /* ... */ }
Noncompliant Code Example (Concurrent code)
This noncompliant code example uses an AtomicInteger
which is part of the concurrency utilities. The concurrency utilities do not enforce checks for integer overflow.
class InventoryManager { private final AtomicInteger itemsInInventory = new AtomicInteger(100); //... public final void returnItem() { itemsInInventory++; } }
Consequently, itemsInInventory
may wrap around to Integer.MIN_VALUE
after the increment operation.
Noncompliant Code Example (Concurrent code - TOCTOU condition in check)
This noncompliant code example install a check for integer overflow, however, there is a time-of-check-time-of-use vulnerability between the check and the increment operation.
class InventoryManager { private volatile int itemsInInventory = 100; // ... public final void returnItem() { if (itemsInInventory == Integer.MAX_VALUE) { throw new IllegalStateException("Out of bounds"); } itemsInInventory++; } }
Compliant Solution (java.util.concurrent.atomic classes
)
The java.util.concurrent
utilities can be used to atomically manipulate a shared variable. This compliant solution defines intemsInInventory
as a java.util.concurrent.atomic.AtomicInteger
variable, allowing composite operations to be performed atomically.
class InventoryManager { private final AtomicInteger itemsInInventory = new AtomicInteger(100); public final void returnItem() { while (true) { int old = itemsInInventory.get(); if (old == Integer.MAX_VALUE) { throw new IllegalStateException("Out of bounds"); } int next = old + 1; // Increment if (itemsInInventory.compareAndSet(old, next)) { break; } } // end while } // end removeItem() }
The compareAndSet()
method takes two arguments, the expected value of a variable when the method is invoked and the updated value. This compliant solution uses this method to atomically set the value of itemsInInventory
to the updated value if and only if the current value equals the expected value [[API 06]]. The while loop ensures that the removeItem()
method succeeds in decrementing the most recent value of itemsInInventory
as long as the inventory count is greater than MIN_INVENTORY
. Refer to [CON01-J. Ensure that compound operations on shared variables are atomic] for more details.
Exceptions
EX1: Depending on the functionality, integer overflow may be benign. For instance, the Object.hashcode()
method may return all representable values of type int
.
Risk Assessment
Failure to perform explicit range checking can lead to integer overflows causing unexpected program control flow or unanticipated program behavior.
Rule |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
---|---|---|---|---|---|
INT00- J |
medium |
unlikely |
medium |
P4 |
L3 |
Automated Detection
TODO
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Other Languages
This rule appears in the C Secure Coding Standard as INT32-C. Ensure that operations on signed integers do not result in overflow.
This rule appears in the C++ Secure Coding Standard as INT32-CPP. Ensure that operations on signed integers do not result in overflow.
References
[[SCG 07]] Introduction
[[JLS 03]] 4.2.2 Integer Operations and 15.22 Bitwise and Logical Operators
[[Tutorials 08]] Primitive Data Types
[[Seacord 05]] Chapter 5. Integers
[[Bloch 05]] Puzzle 27: Shifty i's
[[MITRE 09]] CWE ID 682 "Incorrect Calculation", CWE ID 190 "Integer Overflow or Wraparound", CWE ID 191 "Integer Underflow (Wrap or Wraparound)"
06. Integers (INT) 06. Integers (INT) INT01-J. Range check before casting integers to narrower types