Housekeeping

1. Housekeeping • Project/assignment 6/quiz 6 questions? • Quiz 6: Query optimization, database security • At 9:10, you’ll have 15 minutes to do on-line student ratings • Office hours today: 10:30-12:30 • Offce hours next week: M/W/F 10:30-12:30

2. Security: Access Control, SQL Injection Attacks Based upon slides from: classes.soe.ucsc.edu/.../SQL%20Injection%20Attacks.ppt homes.cs.washington.edu/~suciu/current-trends.ppt www.cse.iitb.ac.in/dbms/Data/.../DBSecurity-Overview.ppt

3. Data Security • Protection from malicious attempts to steal (view) or modify data. • The science and study of methods of protecting data (...) from unauthorized disclosure and modification • Data Security = Confidentiality + Integrity

4. Traditional Data Security • Security in statistical databases = Theory • http://en.wikipedia.org/wiki/Statistical_database • In a statistical database, it is often desired to allow query access only to aggregate data, not individual records. Securing such a database is a difficult problem, since intelligent users can use a combination of aggregate queries to derive information about a single individual. • Security in SQL = Access control + Views

5. [Griffith&Wade'76, Fagin'78] Access Control in SQL GRANT privileges ON object TO users [WITH GRANT OPTIONS] privileges = SELECT | INSERT | DELETE | . . . object = table | attribute REVOKE privileges ON object FROM users [CASCADE ]

6. Access Control in MySQL • http://dev.mysql.com/doc/refman/5.0/en/privilege-system.html • The primary function of the MySQL privilege system is to authenticate a user who connects from a given host and to associate that user with privileges on a database such as SELECT, INSERT, UPDATE, and DELETE • There are some things that you cannot do with the MySQL privilege system: • You cannot explicitly specify that a given user should be denied access. That is, you cannot explicitly match a user and then refuse the connection. • You cannot specify that a user has privileges to create or drop tables in a database but not to create or drop the database itself. • A password applies globally to an account. You cannot associate a password with a specific object such as a database, table, or routine.

7. Views in SQL A SQL View = (almost) any SQL query • Typically used as: CREATE VIEW pmpStudents AS SELECT * FROM Students WHERE… GRANT SELECT ON pmpStudents TO DavidRispoli

8. Views in MySQL • http://dev.mysql.com/doc/refman/5.0/en/create-view.html • CREATE [OR REPLACE] [ALGORITHM = {UNDEFINED | MERGE | TEMPTABLE}] [DEFINER = { user | CURRENT_USER }] [SQL SECURITY { DEFINER | INVOKER }] VIEW view_name [(column_list)] AS select_statement [WITH [CASCADED | LOCAL] CHECK OPTION] • The DEFINER and SQL SECURITY clauses determine which MySQL account to use when checking access privileges for the view when a statement is executed that references the view.

9. Limitations: Often no row level access control Note: DB specific – fine-grained access control is an active area of improvement Table creator owns the data (not always fair) … or spectacular failure: Only ~30% assign privileges to users/roles And then to protect entire tables, not columns Summary of SQL Security Access control = great success story of the DB community...

10. MySQL security • http://dev.mysql.com/doc/refman/5.0/en/security.html Many aspects: • General factors that affect security. These include choosing good passwords, not granting unnecessary privileges to users, ensuring application security by preventing SQL injections and data corruption, and others. See Section 6.1, “General Security Issues”. • Security of the installation itself. The data files, log files, and the all the application files of your installation should be protected to ensure that they are not readable or writable by unauthorized parties. For more information, see Section 2.18, “Postinstallation Setup and Testing”.

11. MySQL security • Access control and security within the database system itself, including the users and databases granted with access to the databases, views and stored programs in use within the database. For more information, see Section 6.2, “The MySQL Access Privilege System”, and Section 6.3, “MySQL User Account Management”. • Network security of MySQL and your system. The security is related to the grants for individual users, but you may also wish to restrict MySQL so that it is available only locally on the MySQL server host, or to a limited set of other hosts. • Ensure that you have adequate and appropriate backups of your database files, configuration and log files. Also be sure that you have a recovery solution in place and test that you are able to successfully recover the information from your backups. See Chapter 7, Backup and Recovery.

12. SQL Injection Attacks

13. http://www.circleid.com/posts/20130325_sql_injection_in_the_wild/http://www.circleid.com/posts/20130325_sql_injection_in_the_wild/

14. What is a SQL Injection Attack? • Many web applications take user input from a form • Often this user input is used literally in the construction of a SQL query submitted to a database. For example: • SELECT productdata FROM table WHERE productname = ‘user input product name’; • A SQL injection attack involves placing SQL statements in the user input

15. SQL Injection Attacks on the rise • https://www.net-security.org/secworld.php?id=13313 • “Many, many sites have lost customer data in this way,” said Chris Hinkley, Senior Security Engineer at FireHost. “SQL Injection attacks are often automated and many website owners may be blissfully unaware that their data could actively be at risk. These attacks can be detected and businesses should be taking basic and blanket steps to block attempted SQL Injection, as well as the other types of attacks we frequently see.”

16. 2012 News of SQL attacks • http://www.mysqlperformanceblog.com/2012/07/18/sql-injection-still-a-problem/ • An SQL injection vulnerability resulted in an urgent June bugfix release of Ruby on Rails 3.x. • Yahoo! Voices was hacked in July. The attack acquired 453,000 user email addresses and passwords. The perpetrators claimed to have used union-based SQL injection to break in. • LinkedIn.com leaked 6.5 million user credentials in June. A class action lawsuit alleges that the attack was accomplished with SQL injection. • SQL injection was documented as a security threat in 1998, but new incidents still occur every month. Making honest mistakes, developers fail to defend against this means of attack, and the security of online data is at risk for all of us because of it.

17. Some good sites to learn more Prevention guide (with sample code in many languages): • http://bobby-tables.com/ Tutorials: • (webinar) http://www.percona.com/webinars/2012-07-25-sql-injection-myths-and-fallacies • http://www.netrostar.com/SQL-Injection-Attack • http://www.unixwiz.net/techtips/sql-injection.html Cool site that let’s you try out attacks on a sample DB and explains why they work • http://sqlzoo.net/hack/ Research paper on how to retrofit existing websites to combat SQL injection attacks • http://lersse-dl.ece.ubc.ca/record/205/files/paper.pdf

18. An Example SQL Injection Attack blah‘ OR ‘x’ = ‘x Product Search: • This input is put directly into the SQL statement within the Web application: • $query = “SELECT prodinfo FROM prodtable WHERE prodname = ‘” . $_POST[‘prod_search’] . “’”; • Creates the following SQL: • SELECT prodinfo FROM prodtable WHERE prodname = ‘blah‘ OR ‘x’ = ‘x’ • Attacker has now successfully caused the entire database to be returned.

19. A More Malicious Example • What if the attacker had instead entered: • blah‘; DROP TABLE prodinfo; -- • Results in the following SQL: • SELECT prodinfo FROM prodtable WHERE prodname = ‘blah’; DROP TABLE prodinfo; --’ • Note how comment (--) consumes the final quote • Causes the entire database to be deleted • Depends on knowledge of table name • This is sometimes exposed to the user in debug code called during a database error • Use non-obvious table names, and never expose them to user • Usually data destruction is not your worst fear, as there is low economic motivation

20. Other injection possibilities • Using SQL injections, attackers can: • Add new data to the database • Could be embarrassing to find yourself selling politically incorrect items on an eCommerce site • Perform an INSERT in the injected SQL • Modify data currently in the database • Could be very costly to have an expensive item suddenly be deeply ‘discounted’ • Perform an UPDATE in the injected SQL • Often can gain access to other user’s system capabilities by obtaining their password

21. Best defence • If possible, use bound variables with prepared statements • Many libraries allow you to bind inputs to variables inside a SQL statement • PERL example (from http://www.unixwiz.net/techtips/sql-injection.html) $sth = $dbh->prepare("SELECT email, userid FROM members WHERE email = ?;"); $sth->execute($email); See http://bobby-tables.com for example code in many languages

22. How does this prevent an attack? • The SQL statement you pass to prepare is parsed and compiled by the database server. • By specifying parameters (either a ? or a named parameter like :name) you tell the database engine what to filter on. • Then when you call execute the prepared statement is combined with the parameter values you specify. • It works because the parameter values are combined with the compiled statement, not a SQL string. • SQL injection works by tricking the script into including malicious strings when it creates SQL to send to the database. So by sending the actual SQL separately from the parameters you limit the risk of ending up with something you didn't intend.

23. Other Defenses • Use provided functions for escaping strings • Many attacks can be thwarted by simply using the SQL string escaping mechanism • ‘ \’ and “  \” • mysql_real_escape_string() is the preferred function for this • Will not guard against all attacks • Consider: • SELECT fields FROM table WHERE id = 23 OR 1=1 • No quotes here!

24. More Defenses • Check syntax of input for validity • Many classes of input have fixed languages • Email addresses, dates, part numbers, etc. • Verify that the input is a valid string in the language • Some languages allow problematic characters (e.g., ‘*’ in email); may decide to not allow these • Exclude quotes and semicolons • Not always possible: consider the name Bill O’Reilly • Want to allow the use of single quotes in names • Have length limits on input • Many SQL injection attacks depend on entering long strings

25. Even More Defenses • Scan query string for undesirable word combinations that indicate SQL statements • INSERT, DROP, etc. • If you see these, can check against SQL syntax to see if they represent a statement or valid user input • Limit database permissions and segregate users • If you’re only reading the database, connect to database as a user that only has read permissions • Never connect as a database administrator in your web application

26. And Yet More Defenses • Configure database error reporting • Default error reporting often gives away information that is valuable for attackers (table name, field name, etc.) • Configure so that this information is never exposed to a user