The Java garbage collector is called to free unreferenced but as-yet unreleased memory. However, the garbage collector cannot free nonmemory resources such as open file descriptors and database connections. Consequently, failing to release such resources can lead to resource exhaustion attacks. In addition, programs can experience resource starvation while waiting for a finalizer to release resources such as Lock or Semaphore objects. This can occur because Java lacks any temporal guarantee of when finalizers execute other than "sometime before program termination." Finally, output streams may cache object references; such cached objects are not garbage-collected until after the output stream is closed. Consequently, output streams should be closed promptly after use.
A program may leak resources when it relies on finalizers If the program relies on finalize() to release system resources , or when there is confusion over which part of the program is responsible for releasing system resources, then there exists a possibility for a potential resource leak. In a busy system, there might be a time gap the delay before the finalize() method finalizer is called for an object . An attacker might exploit this vulnerability to induce a Denial of Service attack. Rule OBJ02-J has more information on the usage of finalizers.
If there is unreleased memory, eventually the Java garbage collector will be called to free memory; however, if the program relies on non-memory resources like file descriptors and database connections, unreleased resources might lead the program to prematurely exhaust it's pool of resources. In addition, if the program uses resources like Lock or Semaphore, waiting for finalize() to release the resources may lead to resource starvation.
Noncompliant Code Example
This problem is aggravated in the case of database connections. Traditionally, database servers allow a fixed number of connections, which may be dependant on configuration or licensing issues. Not releasing such connections could lead to rapid exhaustion of available connections.
provides a window of vulnerability during which an attacker could induce a denial-of-service (DoS) attack. Consequently, resources other than raw memory must be explicitly freed in nonfinalizer methods because of the unsuitability of using finalizers. See MET12-J. Do not use finalizers for additional reasons to avoid the use of finalizers.
Note that on Windows systems, attempts to delete open files fail silently (see FIO03-J. Remove temporary files before termination for more information).
Noncompliant Code Example (File Handle)
This noncompliant code example opens a file and uses it but fails to explicitly close the file:
| Code Block | ||
|---|---|---|
| ||
public int processFile(String fileName)
throws IOException, FileNotFoundException {
FileInputStream stream = new FileInputStream(fileName);
BufferedReader bufRead =
new BufferedReader(new InputStreamReader(stream));
String line;
while ((line = bufRead.readLine()) != null) {
sendLine(line);
}
return 1;
}
|
Compliant Solution
This compliant solution releases all acquired resources, regardless of any exceptions that might occur. Even though dereferencing bufRead might result in an exception, the FileInputStream object is closed as required.
| Code Block | ||
|---|---|---|
| ||
try {
final FileInputStream stream = new FileInputStream(fileName);
try {
final BufferedReader bufRead =
new BufferedReader(new InputStreamReader(stream));
String line;
while ((line = bufRead.readLine()) != null) {
sendLine(line);
}
} finally {
if (stream != null) {
try {
stream.close();
} catch (IOException e) {
// Forward to handler
}
}
}
} catch (IOException e) {
// Forward to handler
}
|
Compliant Solution (try-with-resources)
This compliant solution uses the try-with-resources statement, introduced in Java SE 7, to release all acquired resources regardless of any exceptions that might occur:
| Code Block | ||
|---|---|---|
| ||
try (FileInputStream stream = new FileInputStream(fileName);
BufferedReader bufRead =
new BufferedReader(new InputStreamReader(stream))) {
String line;
while ((line = bufRead.readLine()) != null) {
sendLine(line);
}
} catch (IOException e) {
// Forward to handler
}
|
The try-with-resources construct sends any IOException to the catch clause, where it is forwarded to an exception handler. Exceptions generated during the allocation of resources (that is, the creation of the FileInputStream or BufferedReader), as well as any IOException thrown during execution of the while loop and any IOException generated by closing bufRead or stream, are included.
Noncompliant Code Example (SQL Connection)
The problem of resource pool exhaustion is exacerbated in the case of database connections. Many database servers allow only a fixed number of connections, depending on configuration and licensing. Consequently, failure to release database connections can result in rapid exhaustion of available connections. This noncompliant code example fails to close the connection when an error occurs during execution of the SQL statement or during processing of the results:
| Code Block | ||
|---|---|---|
| ||
| Code Block | ||
| ||
public void getResults(String sqlQuery) { try { Connection conn = getConnection(); Statement stmt = conn.createStatement(); ResultSet rs = stmt.executeQuery(sqlQuery); processResults(rs); stmt.close(); conn.close(); } catch (SQLException e) { /* Forward to handler */ } } |
In the case above, if an error occurs while executing the statement, or while processing the results of the statement, the connection is not closed. The use of a finally block can be used to ensure that close statements are eventually called.
Noncompliant Code Example
Noncompliant Code Example
This noncompliant code example attempts to address exhaustion of database connections by adding cleanup code in a finally block. However, rs, stmt, or conn could be null, causing the code in the finally block to throw a NullPointerExceptionHowever, while being slightly better, this code is also non-compliant. Both rs and stmt might be null.
| Code Block | ||
|---|---|---|
| ||
Statement stmt = null; ResultSet rs = null; Connection conn = getConnection(0); try { stmt = conn.createStatement(); rs = stmt.executeQuery(sqlQuery); processResults(rs); } catch(SQLException e) { // Forward to handler } finally { rs.close(); stmtstmt.close(); conn.close(); } } |
Noncompliant Code Example
Again, while being still better, the code is still non-compliant. This is because rsIn this noncompliant code example, the call to rs.close() or the call to stmt.close() might itself result in throw a SQLException. Consequently, and so stmtconn.close() will is never be calledcalled, which violates ERR05-J. Do not let checked exceptions escape from a finally block.
| Code Block | ||
|---|---|---|
| ||
Statement stmt = null; ResultSet rs = null; Connection conn = getConnection(); try { stmt = conn.createStatement(); rs = stmt.executeQuery(sqlQuery); processResults(rs); } catch (SQLException e) { } // Forward to handler } finally { if if(rs != null) { rs.close(); } } if(stmtif (stmt != null) { stmt.close(); } if (conn != null) { stmt conn.close(); } } } |
Compliant Solution
This compliant solution shows how to ensure ensures that resources have been released.are released as required:
| Code Block | ||
|---|---|---|
| ||
Statement stmt = null; ResultSet rs = null; Connection conn = getConnection(); try { stmt = conn.createStatement(); rs = stmt.executeQuery(sqlQuery); processResults(rs); } catch (SQLException e) { } // Forward to handler } finally { try { if if(rs != null) { rs.close();} } catch (SQLException e) }{ // }Forward finallyto (handler } finally { try { if if(stmt != null) { stmt.close();} } catch (SQLException e) { } // Forward to handler } finally { finallytry { if (conn != null) {conn.close(); } } } |
Noncompliant Code Example
The worst form of non-compliance is not calling methods to release the resource at all. If files are opened, they must be explicitly closed when their work is done.
| Code Block | ||
|---|---|---|
| ||
public int processFile(String fileName) throws IOException, FileNotFoundException catch (SQLException e) { FileInputStream stream = new FileInputStream(fileName); BufferedReader bufRead = new BufferedReader(stream);// Forward to handler String line;} while((line=bufRead.readLine())!=null) { sendLine(line); } return 1; } } } |
Compliant
...
Solution (try-with-resources)
This compliant solution uses the try-with-resources construct, introduced in Java SE 7, to ensure that resources are released as required:A compliant code example would release all acquired resources, regardless of any exceptions which might occur. Hence, in the compliant code below, even though bufRead might result in an exception, if a FileInputStream object was instantiated, it will be closed.
| Code Block | ||
|---|---|---|
| ||
FileInputStream streamtry (Connection conn = nullgetConnection(); BufferedReader bufRead = null; String line; try { Statement streamstmt = new FileInputStream(fileNameconn.createStatement(); bufFread = new BufferedReader(stream); while((line=bufRead.readLine())!=null) { sendLine(line); } ResultSet rs = stmt.executeQuery(sqlQuery)) { processResults(rs); } catch (IOExceptionSQLException e) { } catch// {FileNotFoundExceptionForward e) { } finally { stream.close(); } |
Risk Assessment
to handler
}
|
The try-with-resources construct sends any SQLException to the catch clause, where it is forwarded to an exception handler. Exceptions generated during the allocation of resources (that is, the creation of the Connection, Statement, or ResultSet), as well as any SQLException thrown by processResults() and any SQLException generated by closing rs, stmt, or conn are included.
Risk Assessment
Failure to explicitly release nonmemory system resources when they are no longer needed can result in Acquiring non-memory system resources and not releasing them explicitly might lead to resource exhaustion.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
|---|
FIO04-J |
Low |
Probable |
Medium | P4 | L3 |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
References
Automated Detection
Although sound automated detection of this vulnerability is not feasible in the general case, many interesting cases can be soundly detected.
Some static analysis tools can detect cases in which there is leak of a socket resource or leak of a stream representing a file or other system resources.
Tool | Version | Checker | Description | ||||||
|---|---|---|---|---|---|---|---|---|---|
| CodeSonar |
| JAVA.ALLOC.LEAK.NOTCLOSED | Closeable Not Closed (Java) | ||||||
| Coverity | 7.5 | ITERATOR | Implemented | ||||||
| Parasoft Jtest |
| CERT.FIO04.LEAKS CERT.FIO04.CIO CERT.FIO04.CCR | Ensure resources are deallocated Close input and output resources in "finally" blocks Close all "java.io.Closeable" resources in a "finally" block | ||||||
| SonarQube |
| S2095 | Implemented |
Related Guidelines
CWE-404, Improper Resource Shutdown or Release |
Android Implementation Details
The compliant solution (try-with-resources) is not yet supported at API level 18 (Android 4.3).
Bibliography
[API 2014] | |
The |
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