Regular expressions (regex) are widely used to match strings of text. For example, the POSIX grep utility supports regular expressions for finding patterns in the specified text. For introductory information on regular expressions, see the Java Tutorials [Java Tutorials]. The java.util.regex package provides the Pattern class that encapsulates a compiled representation of a regular expression and the Matcher class, which is an engine that uses a Pattern to perform matching operations on a CharSequence.
Java's powerful regex facilities must be protected from misuse. An attacker may supply a malicious input that modifies the original regular expression in such a way that the regex fails to comply with the program's specification. This attack vector, called a regex injection, might affect control flow, cause information leaks, or result in denial-of-service (DoS) vulnerabilities.
Certain constructs and properties of Java regular expressions are susceptible to exploitation:
- Matching flags: Untrusted inputs may override matching options that may or may not have been passed to the
Pattern.compile()method. - Greediness: An untrusted input may attempt to inject a regex that changes the original regex to match as much of the string as possible, exposing sensitive information.
- Grouping: The programmer can enclose parts of a regular expression in parentheses to perform some common action on the group. An attacker may be able to change the groupings by supplying untrusted input.
Untrusted input should be sanitized before use to prevent regex injection. When the user must specify a regex as input, care must be taken to ensure that the original regex cannot be modified without restriction. Whitelisting characters (such as letters and digits) before delivering the user-supplied string to the regex parser is a good input sanitization strategy. A programmer must provide only a very limited subset of regular expression functionality to the user to minimize any chance of misuse.
Regex Injection Example
Suppose a system log file contains messages output by various system processes. Some processes produce public messages, and some processes produce sensitive messages marked "private." Here is an example log file:
10:47:03 private[423] Successful logout name: usr1 ssn: 111223333 10:47:04 public[48964] Failed to resolve network service 10:47:04 public[1] (public.message[49367]) Exited with exit code: 255 10:47:43 private[423] Successful login name: usr2 ssn: 444556666 10:48:08 public[48964] Backup failed with error: 19
A user wishes to search the log file for interesting messages but must be prevented from seeing the private messages. A program might accomplish this by permitting the user to provide search text that becomes part of the following regex:
(.*? +public\[\d+\] +.*<SEARCHTEXT>.*)
However, if an attacker can substitute any string for <SEARCHTEXT>, he can perform a regex injection with the following text:
.*)|(.*
When injected into the regex, the regex becomes
(.*? +public\[\d+\] +.*.*)|(.*.*)
This regex will match any line in the log file, including the private ones.
Noncompliant Code Example
This noncompliant code example searches a log file using search terms from an untrusted user:
import java.io.FileInputStream;
import java.io.IOException;
import java.nio.CharBuffer;
import java.nio.MappedByteBuffer;
import java.nio.channels.FileChannel;
import java.nio.charset.Charset;
import java.nio.charset.CharsetDecoder;
import java.util.regex.Matcher;
import java.util.regex.Pattern;
public class LogSearch {
public static void FindLogEntry(String search) {
// Construct regex dynamically from user string
String regex = "(.*? +public\\[\\d+\\] +.*" + search + ".*)";
Pattern searchPattern = Pattern.compile(regex);
try (FileInputStream fis = new FileInputStream("log.txt")) {
FileChannel channel = fis.getChannel();
// Get the file's size and map it into memory
long size = channel.size();
final MappedByteBuffer mappedBuffer = channel.map(
FileChannel.MapMode.READ_ONLY, 0, size);
Charset charset = Charset.forName("ISO-8859-15");
final CharsetDecoder decoder = charset.newDecoder();
// Read file into char buffer
CharBuffer log = decoder.decode(mappedBuffer);
Matcher logMatcher = searchPattern.matcher(log);
while (logMatcher.find()) {
String match = logMatcher.group();
if (!match.isEmpty()) {
System.out.println(match);
}
}
} catch (IOException ex) {
System.err.println("thrown exception: " + ex.toString());
Throwable[] suppressed = ex.getSuppressed();
for (int i = 0; i < suppressed.length; i++) {
System.err.println("suppressed exception: "
+ suppressed[i].toString());
}
}
return;
}
This code permits an attacker to perform a regex injection.
Compliant Solution (Whitelisting)
This compliant solution sanitizes the search terms at the beginning of the FindLogEntry(), filtering out nonalphanumeric characters (except space and single quote):
public static void FindLogEntry(String search) {
// Sanitize search string
StringBuilder sb = new StringBuilder(search.length());
for (int i = 0; i < search.length(); ++i) {
char ch = search.charAt(i);
if (Character.isLetterOrDigit(ch) || ch == ' ' || ch == '\'') {
sb.append(ch);
}
}
search = sb.toString();
// Construct regex dynamically from user string
String regex = "(.*? +public\\[\\d+\\] +.*" + search + ".*)";
// ...
}
This solution prevents regex injection but also restricts search terms. For example, a user may no longer search for "name =" because nonalphanumeric characters are removed from the search term.
Compliant Solution (Pattern.quote())
This compliant solution sanitizes the search terms by using Pattern.quote() to escape any malicious characters in the search string. Unlike the previous compliant solution, a search string using punctuation characters, such as "name =" is permitted.
public static void FindLogEntry(String search) {
// Sanitize search string
search = Pattern.quote(search);
// Construct regex dynamically from user string
String regex = "(.*? +public\\[\\d+\\] +.*" + search + ".*)";
// ...
}
The Matcher.quoteReplacement() method can be used to escape strings used when doing regex substitution.
Compliant Solution
Another method of mitigating this vulnerability is to filter out the sensitive information prior to matching. Such a solution would require the filtering to be done every time the log file is periodically refreshed, incurring extra complexity and a performance penalty. Sensitive information may still be exposed if the log format changes but the class is not also refactored to accommodate these changes.
Risk Assessment
Failing to sanitize untrusted data included as part of a regular expression can result in the disclosure of sensitive information.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
|---|---|---|---|---|---|
IDS08-J | Medium | Unlikely | Medium | P4 | L3 |
Automated Detection
| Tool | Version | Checker | Description |
|---|---|---|---|
| The Checker Framework | 2.1.3 | Tainting Checker | Trust and security errors (see Chapter 8) |
| CodeSonar | 8.1p0 | JAVA.IO.TAINT.REGEX | Tainted Regular Expression (Java) |
| SonarQube | 9.9 | Regular expressions should not be vulnerable to Denial of Service attacks |
Related Guidelines
Bibliography
4 Comments
Robert Seacord
I've made some changes to improve the vocabulary. A "regex" is a "regular expression" but is not a "regular expression engine" so you would no pass things to it. This rule still interchanges "regex" and "regular expression". I'm somewhat tempted to just "regular expression" uniformly as this is what the Oracle documentation appears to do.
David Nault
As an alternative to whitelisting, call Pattern.quote(String) to escape text used to build a pattern, and Matcher.quoteReplacement(String) to escape replacement test.
David Svoboda
I added a compliant solution showcasing Pattern.quote().
Daniel Grahl
The proposed solutions (whitelisting/quote) look restrictive. This seems to be based on an implicit assumption in the example that the user must not enter any regex as search text. In the general case (i.e., permitting the user to enter benign regexes), those solutions would not help.
The third solution (prior filtering), however, does effectively prevent the injection described in the example, even in case the user input contains a regex itself. An alternative solution would be to validate a user-provided regex first: if it compiles then you cannot break out of the grouping, just because parentheses have to match.