SQL injection vulnerabilities arise in applications where elements of a SQL query originate from an untrusted source. Without precautions, the untrusted data may maliciously alter the query, resulting in information leaks or data modification. The primary means of preventing SQL injection are sanitization and validation, which are typically implemented as parameterized queries and stored procedures.
Suppose a system authenticates users by issuing the following query to a SQL database. If the query returns any results, authentication succeeds; otherwise, authentication fails.
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| ||
SELECT * FROM db_user WHERE username='<USERNAME>' AND
password='<PASSWORD>' |
Suppose an attacker can substitute arbitrary strings for <USERNAME>
and <PASSWORD>
. In that case, the authentication mechanism can be bypassed by supplying the following <USERNAME>
with an arbitrary password:
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| ||
validuser' OR '1'='1
|
The authentication routine dynamically constructs the following query:
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SELECT * FROM db_user WHERE username='validuser' OR '1'='1' AND password='<PASSWORD>'
|
If validuser
is a valid user name, this SELECT
statement yields the validuser
record in the table. The password is never checked because username='validuser'
is true; consequently, the items after the OR
are not tested. As long as the components after the OR
generate a syntactically correct SQL expression, the attacker is granted the access of validuser
.
Similarly, an attacker could supply the following string for <PASSWORD>
with an arbitrary username:
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| ||
' OR '1'='1
|
producing the following query:
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| ||
SELECT * FROM db_user WHERE username='<USERNAME>' AND password='' OR '1'='1'
|
'1'='1'
always evaluates to true, causing the query to yield every row in the database. In this scenario, the attacker would be authenticated without needing a valid username or password.
Noncompliant Code Example
This noncompliant code example shows JDBC code to authenticate a user to a system. The password is passed as a char
array, the database connection is created, and then the passwords are hashed.
Unfortunately, this code example permits a SQL injection attack by incorporating the unsanitized input argument username
into the SQL command, allowing an attacker to inject validuser' OR '1'='1
. The password
argument cannot be used to attack this program because it is passed to the hashPassword()
function, which also sanitizes the input.
Code Block | ||||
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import java.sql.Connection;
import java.sql.DriverManager;
import java.sql.ResultSet;
import java.sql.SQLException;
import java.sql.Statement;
class Login {
public Connection getConnection() throws SQLException {
DriverManager.registerDriver(new
com.microsoft.sqlserver.jdbc.SQLServerDriver());
String dbConnection =
PropertyManager.getProperty("db.connection");
// Can hold some value like
// "jdbc:microsoft:sqlserver://<HOST>:1433,<UID>,<PWD>"
return DriverManager.getConnection(dbConnection);
}
String hashPassword(char[] password) {
// Create hash of password
}
public void doPrivilegedAction(String username, char[] password)
throws SQLException {
Connection connection = getConnection();
if (connection == null) {
// Handle error
}
try {
|
Many programs accept untrusted data originating from unvalidated users, network connections, and other untrusted sources and then pass the (modified or unmodified) data across a trust boundary to a different trusted domain. Frequently the data is in the form of a string with some internal syntactic structure, which the subsystem must parse. Such data must be sanitized both because the subsystem may be unprepared to handle the malformed input and because unsanitized input may include an injection attack.
In particular, programs must sanitize all string data that is passed to command interpreters or parsers so that the resulting string is innocuous in the context in which it is parsed or interpreted.
Many command interpreters and parsers provide their own sanitization and validation methods. When available, their use is preferred over custom sanitization techniques because custom developed sanitization can often neglect special cases or hidden complexities in the parser. Another problem with custom sanitization code is that it may not be adequately maintained when new capabilities are added to the command interpreter or parser software.
SQL Injection
A SQL injection vulnerability arises when the original SQL query can be altered to form an altogether different query. Execution of this altered query may result in information leaks or data modification. The primary means of preventing SQL injection are sanitizing and validating untrusted input and parameterizing queries.
Suppose a database contains user names and passwords used to authenticate users of the system. The user names have a string size limit of 8. The passwords have a size limit of 20.
A SQL command to authenticate a user might take the form:
Code Block |
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SELECT * FROM db_user WHERE username='<USERNAME>' AND
password='<PASSWORD>'
|
If it returns any records, the user name and password are valid.
However, if an attacker can substitute arbitrary strings for <USERNAME>
and <PASSWORD>
, they can perform a SQL injection by using the following string for <USERNAME>
:
Code Block |
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validuser' OR '1'='1
|
When injected into the command, the command becomes:
Code Block |
---|
SELECT * FROM db_user WHERE username='validuser' OR '1'='1' AND password=<PASSWORD>
|
If validuser
is a valid user name, this SELECT
statement selects the validuser
record in the table. The password is never checked because username='validuser' is true; consequently the items after the OR
are not tested. As long as the components after the OR generate a syntactically correct SQL expression, the attacker is granted the access of validuser
.
Likewise, an attacker could supply a string for <PASSWORD>
such as:
Code Block |
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' OR '1'='1
|
This would yield the following command:
Code Block |
---|
SELECT * FROM db_user WHERE username='' AND password='' OR '1'='1'
|
This time, the '1'='1'
tautology disables both user name and password validation, and the attacker is falsely logged in without a correct login ID or password.
Noncompliant Code Example
This noncompliant code example shows JDBC code to authenticate a user to a system. The password is passed as a char
array, the database connection is created, and then the passwords are hashed.
Unfortunately, this code example permits a SQL injection attack because the SQL statement sqlString
accepts unsanitized input arguments. The attack scenario outlined previously would work as described.
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| ||
class Login { public Connection getConnection() throws SQLException { DriverManager.registerDriver(new com.microsoft.sqlserver.jdbc.SQLServerDriver()); String dbConnection = PropertyManager.getProperty("db.connection"); // can hold some value like // "jdbc:microsoft:sqlserver://<HOST>:1433,<UID>,<PWD>" return DriverManager.getConnection(dbConnection); } String hashPassword(char[] password) { // create hash of password } public void doPrivilegedAction(String username, char[] password) throws SQLException { Connection connection = getConnection(); if (connection == null) { // handle error } try { String pwd = hashPassword(password); String sqlString = "SELECT * FROM db_user WHERE username = '" + username + "' AND password = '" + pwd + "'"; Statement stmt = connection.createStatement(); ResultSet rs = stmt.executeQuery(sqlString); if (!rs.next()) { throw new SecurityException( "User name or password incorrect" ); } // Authenticated; proceed } finally { try { connection.close(); } catch (SQLException x) { // forwardForward to handler } } } } |
...
Noncompliant Code Example (PreparedStatement
)
Fortunately, the The JDBC library provides an API for building SQL commands that sanitize untrusted data. The java.sql.PreparedStatement
class properly escapes input strings, preventing SQL injection when used properlycorrectly. This is an example of component-based sanitization.This compliant solution code example modifies the doPrivilegedAction()
method to use a PreparedStatement
instead of java.sql.Statement
. This code also validates the length of the username
argument, preventing an attacker from submitting an arbitrarily long user nameHowever, the prepared statement still permits a SQL injection attack by incorporating the unsanitized input argument username
into the prepared statement.
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| ||||
public void doPrivilegedAction( String username, char[] password import java.sql.Connection; import java.sql.DriverManager; import java.sql.ResultSet; import java.sql.SQLException; import java.sql.Statement; class Login { public Connection getConnection() throws SQLException { Connection connection = getConnection();DriverManager.registerDriver(new if (connection == null) { com.microsoft.sqlserver.jdbc.SQLServerDriver()); // Handle error String dbConnection = } try { PropertyManager.getProperty("db.connection"); // Can Stringhold pwdsome = hashPassword(password); value like // Ensure that the length of user name is legitimate// "jdbc:microsoft:sqlserver://<HOST>:1433,<UID>,<PWD>" return DriverManager.getConnection(dbConnection); } String hashPassword(char[] password) { // Create if (username.length() > 8) {hash of password } public void doPrivilegedAction( String // Handle errorusername, char[] password ) throws SQLException } { Connection String sqlStringconnection = getConnection(); if (connection == null) "select{ * from db_user where username=? and password=?"; // Handle error } PreparedStatement stmt = connection.prepareStatement(sqlString); try { String stmt.setString(1, usernamepwd = hashPassword(password); stmt.setString(2, pwd); ResultSet rs = stmt.executeQuery();String sqlString = "select * from db_user where username=" + if (!rs.next()) { throw new SecurityException("User name or password incorrect"); } username + " and password =" + pwd; PreparedStatement stmt = connection.prepareStatement(sqlString); // Authenticated, proceed ResultSet rs = stmt.executeQuery(); } finallyif (!rs.next()) { try { throw new SecurityException("User name or connection.close(password incorrect"); } catch (SQLException x) { // forward to handlerAuthenticated; proceed } } finally { try { } connection.close(); } |
Use the set*()
methods of the PreparedStatement
class to enforce strong type checking. This mitigates the SQL injection vulnerability because the input is properly escaped by automatic entrapment within double quotes. Note that prepared statements must be used even with queries that insert data into the database.
XML Injection
Because of its platform independence, flexibility, and relative simplicity, the extensible markup language (XML) has found use in applications ranging from remote procedure calls to systematic storage, exchange, and retrieval of data. However, because of its versatility, XML is vulnerable to a wide spectrum of attacks. One such attack is called XML injection.
A user who has the ability to provide structured XML as input can override the contents of an XML document by injecting XML tags in data fields. These tags are interpreted and classified by an XML parser as executable content and, as a result, may cause certain data members to be overridden.
Consider the following XML code snippet from an online store application, designed primarily to query a back-end database. The user has the ability to specify the quantity of an item available for purchase.
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<item>
<description>Widget</description>
<price>500.0</price>
<quantity>1</quantity>
</item>
|
A malicious user might input the following string instead of a simple number in the quantity
field.
Code Block |
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1</quantity><price>1.0</price><quantity>1
|
Consequently, the XML resolves to the following block:
Code Block |
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<item>
<description>Widget</description>
<price>500.0</price>
<quantity>1</quantity><price>1.0</price><quantity>1</quantity>
</item>
|
A Simple API for XML (SAX) parser (org.xml.sax
and javax.xml.parsers.SAXParser
) interprets the XML such that the second price field overrides the first, leaving the price of the item as $1. Even when it is not possible to perform such an attack, the attacker may be able to inject special characters, such as comment blocks and CDATA
delimiters, which corrupt the meaning of the XML.
Noncompliant Code Example
In this noncompliant code example, a client method uses simple string concatenation to build an XML query to send to a server. XML injection is possible because the method performs no input validation.
catch (SQLException x) {
// Forward to handler
}
}
}
}
|
Compliant Solution (PreparedStatement
)
This compliant solution uses a parametric query with a ?
character as a placeholder for the argument. This code also validates the length of the username
argument, preventing an attacker from submitting an arbitrarily long user name.
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| ||||
public void doPrivilegedAction(
String username, char[] password
) throws SQLException {
Connection connection = getConnection();
if (connection == null) {
// Handle error
}
try {
String pwd = hashPassword(password);
// Validate username length
if (username.length() > 8) {
// Handle error
}
String sqlString =
"select * from db_user where username=? and password=?";
PreparedStatement stmt = connection.prepareStatement(sqlString);
stmt.setString(1, username);
stmt.setString(2, pwd);
ResultSet rs = stmt.executeQuery();
if (!rs.next()) { | ||||
Code Block | ||||
| ||||
private void createXMLStream(BufferedOutputStream outStream, throw new SecurityException("User name or password incorrect"); } // Authenticated; proceed String quantity) throws} IOExceptionfinally { String xmlString; xmlString = "<item>\n<description>Widget</description>\n" +try { connection.close(); "<price>500.0</price>\n" + } catch (SQLException x) { // Forward "<quantity>" + quantity + "</quantity></item>"; outStream.write(xmlString.getBytes()); outStream.flush(); } |
Compliant Solution (Whitelisting)
Depending on the specific data and command interpreter or parser to which data is being sent, appropriate methods must be used to sanitize untrusted user input. This compliant solution uses whitelisting to sanitize the input. In this compliant solution, the method requires that the quantity field must be a number between 0 and 9.
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private void createXMLStream(BufferedOutputStream outStream,
String quantity) throws IOException {
// Write XML string if quantity contains numbers only.
// Blacklisting of invalid characters can be performed
// in conjunction.
if (!Pattern.matches("[0-9]+", quantity)) {
// Format violation
}
String xmlString = "<item>\n<description>Widget</description>\n" +
"<price>500</price>\n" +
"<quantity>" + quantity + "</quantity></item>";
outStream.write(xmlString.getBytes());
outStream.flush();
}
|
Compliant Solution (XML Schema)
A more general mechanism for checking XML for attempted injection is to validate it using a Document Type Definition (DTD) or schema. The schema must be rigidly defined to prevent injections from being mistaken for valid XML. Here is a suitable schema for validating our XML snippet:
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<xs:schema xmlns:xs="http://www.w3.org/2001/XMLSchema">
<xs:element name="item">
<xs:complexType>
<xs:sequence>
<xs:element name="description" type="xs:string"/>
<xs:element name="price" type="xs:decimal"/>
<xs:element name="quantity" type="xs:integer"/>
</xs:sequence>
</xs:complexType>
</xs:element>
</xs:schema>
|
The schema is available as the file schema.xsd
. This compliant solution employs this schema to prevent XML injection from succeeding. It also relies on the CustomResolver
class to prevent XXE attacks. This class, as well as XXE attacks, are described in the subsequent code examples.
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| ||
private void createXMLStream(BufferedOutputStream outStream,
String quantity) throws IOException {
String xmlString;
xmlString = "<item>\n<description>Widget</description>\n" +
"<price>500.0</price>\n" +
"<quantity>" + quantity + "</quantity></item>";
InputSource xmlStream = new InputSource(
new StringReader(xmlString)
);
// Build a validating SAX parser using our schema
SchemaFactory sf
= SchemaFactory.newInstance(XMLConstants.W3C_XML_SCHEMA_NS_URI);
DefaultHandler defHandler = new DefaultHandler() {
public void warning(SAXParseException s)
throws SAXParseException {throw s;}
public void error(SAXParseException s)
throws SAXParseException {throw s;}
public void fatalError(SAXParseException s)
throws SAXParseException {throw s;}
};
StreamSource ss = new StreamSource(new File("schema.xsd"));
try {
Schema schema = sf.newSchema(ss);
SAXParserFactory spf = SAXParserFactory.newInstance();
spf.setSchema(schema);
SAXParser saxParser = spf.newSAXParser();
// To set the custom entity resolver,
// an XML reader needs to be created
XMLReader reader = saxParser.getXMLReader();
reader.setEntityResolver(new CustomResolver());
saxParser.parse(xmlStream, defHandler);
} catch (ParserConfigurationException x) {
throw new IOException("Unable to validate XML", x);
} catch (SAXException x) {
throw new IOException("Invalid quantity", x);
}
// Our XML is valid, proceed
outStream.write(xmlString.getBytes());
outStream.flush();
}
|
Using a schema or DTD to validate XML is convenient when receiving XML that may have been loaded with unsanitized input. If such an XML string has not yet been built, sanitizing input before constructing XML yields better performance.
XML External Entity Attacks (XXE)
An XML document can be dynamically constructed from smaller logical blocks called entities. Entities can be internal, external, or parameter-based. External entities allow the inclusion of XML data from external files.
According to XML W3C Recommendation [W3C 2008], Section 4.4.3, "Included If Validating":
When an XML processor recognizes a reference to a parsed entity, to validate the document, the processor MUST include its replacement text. If the entity is external, and the processor is not attempting to validate the XML document, the processor MAY, but need not, include the entity's replacement text.
An attacker may attempt to cause denial of service or program crashes by manipulating the URI of the entity to refer to special files existing on the local file system, for example, by specifying /dev/random
or /dev/tty
as input URIs. This may crash or block the program indefinitely. This is called an XML external entity (XXE) attack. Because inclusion of replacement text from an external entity is optional, not all XML processors are vulnerable to external entity attacks.
Noncompliant Code Example
This noncompliant code example attempts to parse the file evil.xml
, report any errors, and exit. However, a SAX or a DOM (Document Object Model) parser will attempt to access the URL specified by the SYSTEM
attribute, which means it will attempt to read the contents of the local /dev/tty
file. On POSIX systems, reading this file causes the program to block until input data is supplied to the machine's console. Consequently, an attacker can use this malicious XML file to cause the program to hang.
Code Block | ||
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| ||
class XXE {
private static void receiveXMLStream(InputStream inStream,
DefaultHandler defaultHandler)
throws ParserConfigurationException, SAXException, IOException {
SAXParserFactory factory = SAXParserFactory.newInstance();
SAXParser saxParser = factory.newSAXParser();
saxParser.parse(inStream, defaultHandler);
}
public static void main(String[] args)
throws ParserConfigurationException, SAXException, IOException {
receiveXMLStream(new FileInputStream("evil.xml"),
new DefaultHandler());
}
}
|
This program is subject to a remote XXE attack if the evil.xml
file contains the following:
Code Block | ||
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| ||
<?xml version="1.0"?>
<!DOCTYPE foo SYSTEM "file:/dev/tty">
<foo>bar</foo>
|
This noncompliant code example may also violate rule ERR01-J. Do not allow exceptions to expose sensitive information if the information contained in the exceptions is sensitive.
Compliant Solution (EntityResolver
)
This compliant solution defines a CustomResolver
class that implements the interface org.xml.sax.EntityResolver
. This enables a SAX application to customize handling of external entities. The setEntityResolver()
method registers the instance with the corresponding SAX driver. The customized handler uses a simple whitelist for external entities. The resolveEntity()
method returns an empty InputSource
when an input fails to resolve to any of the specified, safe entity source paths. Consequently, when parsing malicious input, the empty InputSource
returned by the custom resolver causes a java.net.MalformedURLException
to be thrown. Note that you must create an XMLReader
object on which to set the custom entity resolver.
This is an example of component-based sanitization.
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| ||
class CustomResolver implements EntityResolver {
public InputSource resolveEntity(String publicId, String systemId)
throws SAXException, IOException {
// check for known good entities
String entityPath = "/home/username/java/xxe/file";
if (systemId.equals(entityPath)) {
System.out.println("Resolving entity: " + publicId +
" " + systemId);
return new InputSource(entityPath);
} else {
return new InputSource(); // Disallow unknown entities
// by returning a blank path
}
}
}
class XXE {
private static void receiveXMLStream(InputStream inStream,
DefaultHandler defaultHandler)
throws ParserConfigurationException, SAXException, IOException {
SAXParserFactory factory = SAXParserFactory.newInstance();
SAXParser saxParser = factory.newSAXParser();
// To set the Entity Resolver, an XML reader needs to be created
XMLReader reader = saxParser.getXMLReader();
reader.setEntityResolver(new CustomResolver());
reader.setContentHandler(defaultHandler);
InputSource is = new InputSource(inStream);
reader.parse(is);
}
public static void main(String[] args)
throws ParserConfigurationException, SAXException, IOException {
receiveXMLStream(new FileInputStream("evil.xml"),
new DefaultHandler());
}
}
|
Risk Assessment
Failure to sanitize user input before processing or storing it can result in injection attacks.
to handler
}
}
}
|
Use the set*()
methods of the PreparedStatement
class to enforce strong type checking. This technique mitigates the SQL injection vulnerability because the input is properly escaped by automatic entrapment within double quotes. Note that prepared statements must be used even with queries that insert data into the database.
Risk Assessment
Failure to sanitize user input before processing or storing it can result in injection attacks.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|---|---|---|---|---|
IDS00-J | High | Likely | Medium | P18 | L1 |
Automated Detection
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
The Checker Framework |
| Tainting Checker | Trust and security errors (see Chapter 8) | ||||||
CodeSonar |
| JAVA.IO.INJ.SQL | SQL Injection (Java) | ||||||
Coverity | 7.5 | SQLI | Implemented | ||||||
Findbugs | 1.0 | SQL_NONCONSTANT_STRING_PASSED_TO_EXECUTE | Implemented | ||||||
Fortify | 1.0 | HTTP_Response_Splitting | Implemented | ||||||
Klocwork |
| SV.DATA.DB | Implemented | ||||||
Parasoft Jtest |
| CERT.IDS00.TDSQL | Protect against SQL injection | ||||||
SonarQube |
| ||||||||
SpotBugs |
| SQL_NONCONSTANT_STRING_PASSED_TO_EXECUTE | Implemented |
Rule
Severity
Likelihood
Remediation Cost
Priority
Level
IDS00-J
high
probable
medium
P12
Related Vulnerabilities
CVE-2008-2370 describes a a vulnerability in Apache Tomcat 4.1.0 through 4.1.37, 5.5.0 through 5.5.26, and 6.0.0 through 6.0.16. When a RequestDispatcher
is used, Tomcat performs path normalization before removing the query string from the URI, which allows remote attackers to conduct directory traversal attacks and read arbitrary files via a ..
(dot dot) in a request parameter.
Related Guidelines
SEI CERT Perl Coding Standard | IDS33-PL. Sanitize untrusted data passed |
across a trust boundary |
Injection [RST] |
CWE-116, Improper Encoding or Escaping of Output |
Android Implementation Details
This rule uses Microsoft SQL Server as an example to show a database connection. However, on Android, DatabaseHelper
from SQLite is used for a database connection. Because Android apps may receive untrusted data via network connections, the rule is applicable.
Bibliography
A Guide to Building Secure Web Applications and Web Services |
[ |
Seacord 2015] | |
[W3C 2008] | Section 4.4.3, "Included If Validating" |
...