I realize that parameterized SQL queries is the optimal way to sanitize user input when building queries that contain user input, but I'm wondering what is wrong with taking user input and escaping any single quotes and surrounding the whole string with single quotes. Here's the code:
sSanitizedInput = "'" & Replace(sInput, "'", "''") & "'"
Any single-quote the user enters is replaced with double single-quotes, which eliminates the users ability to end the string, so anything else they may type, such as semicolons, percent signs, etc., will all be part of the string and not actually executed as part of the command.
We are using Microsoft SQL Server 2000, for which I believe the single-quote is the only string delimiter and the only way to escape the string delimiter, so there is no way to execute anything the user types in.
I don't see any way to launch an SQL injection attack against this, but I realize that if this were as bulletproof as it seems to me someone else would have thought of it already and it would be common practice.
What's wrong with this code? Is there a way to get an SQL injection attack past this sanitization technique? Sample user input that exploits this technique would be very helpful.
UPDATE:
I still don't know of any way to effectively launch a SQL injection attack against this code. A few people suggested that a backslash would escape one single-quote and leave the other to end the string so that the rest of the string would be executed as part of the SQL command, and I realize that this method would work to inject SQL into a MySQL database, but in SQL Server 2000 the only way (that I've been able to find) to escape a single-quote is with another single-quote; backslashes won't do it.
And unless there is a way to stop the escaping of the single-quote, none of the rest of the user input will be executed because it will all be taken as one contiguous string.
I understand that there are better ways to sanitize input, but I'm really more interested in learning why the method I provided above won't work. If anyone knows of any specific way to mount a SQL injection attack against this sanitization method I would love to see it.
First of all, it's just bad practice. Input validation is always necessary, but it's also always iffy.
Worse yet, blacklist validation is always problematic, it's much better to explicitly and strictly define what values/formats you accept. Admittedly, this is not always possible - but to some extent it must always be done.
Some research papers on the subject:
http://www.imperva.com/docs/WP_SQL_Injection_Protection_LK.pdf
http://www.it-docs.net/ddata/4954.pdf (Disclosure, this last one was mine ;) )
https://www.owasp.org/images/d/d4/OWASP_IL_2007_SQL_Smuggling.pdf (based on the previous paper, which is no longer available)
Point is, any blacklist you do (and too-permissive whitelists) can be bypassed. The last link to my paper shows situations where even quote escaping can be bypassed.
Even if these situations do not apply to you, it's still a bad idea. Moreover, unless your app is trivially small, you're going to have to deal with maintenance, and maybe a certain amount of governance: how do you ensure that its done right, everywhere all the time?
The proper way to do it:
Whitelist validation: type, length, format or accepted values
If you want to blacklist, go right ahead. Quote escaping is good, but within context of the other mitigations.
Use Command and Parameter objects, to preparse and validate
Call parameterized queries only.
Better yet, use Stored Procedures exclusively.
Avoid using dynamic SQL, and dont use string concatenation to build queries.
If using SPs, you can also limit permissions in the database to executing the needed SPs only, and not access tables directly.
you can also easily verify that the entire codebase only accesses the DB through SPs...
Okay, this response will relate to the update of the question:
"If anyone knows of any specific way to mount a SQL injection attack against this sanitization method I would love to see it."
Now, besides the MySQL backslash escaping - and taking into account that we're actually talking about MSSQL, there are actually 3 possible ways of still SQL injecting your code
sSanitizedInput = "'" & Replace(sInput, "'", "''") & "'"
Take into account that these will not all be valid at all times, and are very dependant on your actual code around it:
Second-order SQL Injection - if an SQL query is rebuilt based upon data retrieved from the database after escaping, the data is concatenated unescaped and may be indirectly SQL-injected. See
String truncation - (a bit more complicated) - Scenario is you have two fields, say a username and password, and the SQL concatenates both of them. And both fields (or just the first) has a hard limit on length. For instance, the username is limited to 20 characters. Say you have this code:
username = left(Replace(sInput, "'", "''"), 20)
Then what you get - is the username, escaped, and then trimmed to 20 characters. The problem here - I'll stick my quote in the 20th character (e.g. after 19 a's), and your escaping quote will be trimmed (in the 21st character). Then the SQL
sSQL = "select * from USERS where username = '" + username + "' and password = '" + password + "'"
combined with the aforementioned malformed username will result in the password already being outside the quotes, and will just contain the payload directly.
3. Unicode Smuggling - In certain situations, it is possible to pass a high-level unicode character that looks like a quote, but isn't - until it gets to the database, where suddenly it is. Since it isn't a quote when you validate it, it will go through easy... See my previous response for more details, and link to original research.
In a nutshell: Never do query escaping yourself. You're bound to get something wrong. Instead, use parameterized queries, or if you can't do that for some reason, use an existing library that does this for you. There's no reason to be doing it yourself.
I realize this is a long time after the question was asked, but ..
One way to launch an attack on the 'quote the argument' procedure is with string truncation.
According to MSDN, in SQL Server 2000 SP4 (and SQL Server 2005 SP1), a too long string will be quietly truncated.
When you quote a string, the string increases in size. Every apostrophe is repeated.
This can then be used to push parts of the SQL outside the buffer. So you could effectively trim away parts of a where clause.
This would probably be mostly useful in a 'user admin' page scenario where you could abuse the 'update' statement to not do all the checks it was supposed to do.
So if you decide to quote all the arguments, make sure you know what goes on with the string sizes and see to it that you don't run into truncation.
I would recommend going with parameters. Always. Just wish I could enforce that in the database. And as a side effect, you are more likely to get better cache hits because more of the statements look the same. (This was certainly true on Oracle 8)
I've used this technique when dealing with 'advanced search' functionality, where building a query from scratch was the only viable answer. (Example: allow the user to search for products based on an unlimited set of constraints on product attributes, displaying columns and their permitted values as GUI controls to reduce the learning threshold for users.)
In itself it is safe AFAIK. As another answerer pointed out, however, you may also need to deal with backspace escaping (albeit not when passing the query to SQL Server using ADO or ADO.NET, at least -- can't vouch for all databases or technologies).
The snag is that you really have to be certain which strings contain user input (always potentially malicious), and which strings are valid SQL queries. One of the traps is if you use values from the database -- were those values originally user-supplied? If so, they must also be escaped. My answer is to try to sanitize as late as possible (but no later!), when constructing the SQL query.
However, in most cases, parameter binding is the way to go -- it's just simpler.
Input sanitation is not something you want to half-ass. Use your whole ass. Use regular expressions on text fields. TryCast your numerics to the proper numeric type, and report a validation error if it doesn't work. It is very easy to search for attack patterns in your input, such as ' --. Assume all input from the user is hostile.
It's a bad idea anyway as you seem to know.
What about something like escaping the quote in string like this: \'
Your replace would result in: \''
If the backslash escapes the first quote, then the second quote has ended the string.
Simple answer: It will work sometimes, but not all the time.
You want to use white-list validation on everything you do, but I realize that's not always possible, so you're forced to go with the best guess blacklist. Likewise, you want to use parametrized stored procs in everything, but once again, that's not always possible, so you're forced to use sp_execute with parameters.
There are ways around any usable blacklist you can come up with (and some whitelists too).
A decent writeup is here: http://www.owasp.org/index.php/Top_10_2007-A2
If you need to do this as a quick fix to give you time to get a real one in place, do it. But don't think you're safe.
There are two ways to do it, no exceptions, to be safe from SQL-injections; prepared statements or prameterized stored procedures.
If you have parameterised queries available you should be using them at all times. All it takes is for one query to slip through the net and your DB is at risk.
Patrick, are you adding single quotes around ALL input, even numeric input? If you have numeric input, but are not putting the single quotes around it, then you have an exposure.
Yeah, that should work right up until someone runs SET QUOTED_IDENTIFIER OFF and uses a double quote on you.
Edit: It isn't as simple as not allowing the malicious user to turn off quoted identifiers:
The SQL Server Native Client ODBC driver and SQL Server Native Client OLE DB Provider for SQL Server automatically set QUOTED_IDENTIFIER to ON when connecting. This can be configured in ODBC data sources, in ODBC connection attributes, or OLE DB connection properties. The default for SET QUOTED_IDENTIFIER is OFF for connections from DB-Library applications.
When a stored procedure is created, the SET QUOTED_IDENTIFIER and SET ANSI_NULLS settings are captured and used for subsequent invocations of that stored procedure.
SET QUOTED_IDENTIFIER also corresponds to the QUOTED_IDENTIFER setting of ALTER DATABASE.
SET QUOTED_IDENTIFIER is set at parse time. Setting at parse time means that if the SET statement is present in the batch or stored procedure, it takes effect, regardless of whether code execution actually reaches that point; and the SET statement takes effect before any statements are executed.
There's a lot of ways QUOTED_IDENTIFIER could be off without you necessarily knowing it. Admittedly - this isn't the smoking gun exploit you're looking for, but it's a pretty big attack surface. Of course, if you also escaped double quotes - then we're back where we started. ;)
Your defence would fail if:
the query is expecting a number rather than a string
there were any other way to represent a single quotation mark, including:
an escape sequence such as \039
a unicode character
(in the latter case, it would have to be something which were expanded only after you've done your replace)
What ugly code all that sanitisation of user input would be! Then the clunky StringBuilder for the SQL statement. The prepared statement method results in much cleaner code, and the SQL Injection benefits are a really nice addition.
Also why reinvent the wheel?
Rather than changing a single quote to (what looks like) two single quotes, why not just change it to an apostrophe, a quote, or remove it entirely?
Either way, it's a bit of a kludge... especially when you legitimately have things (like names) which may use single quotes...
NOTE: Your method also assumes everyone working on your app always remembers to sanitize input before it hits the database, which probably isn't realistic most of the time.
I'm not sure about your case, but I just encountered a case in Mysql that Replace(value, "'", "''") not only can't prevent SQL injection, but also causes the injection.
if an input ended with \', it's OK without replace, but when replacing the trailing ', the \ before end of string quote causes the SQL error.
While you might find a solution that works for strings, for numerical predicates you need to also make sure they're only passing in numbers (simple check is can it be parsed as int/double/decimal?).
It's a lot of extra work.
It might work, but it seems a little hokey to me. I'd recommend verifing that each string is valid by testing it against a regular expression instead.
Yes, you can, if...
After studying the topic, I think input sanitized as you suggested is safe, but only under these rules:
you never allow string values coming from users to become anything else than string literals (i.e. avoid giving configuration option: "Enter additional SQL column names/expressions here:"). Value types other than strings (numbers, dates, ...): convert them to their native data types and provide a routine for SQL literal from each data type.
SQL statements are problematic to validate
you either use nvarchar/nchar columns (and prefix string literals with N) OR limit values going into varchar/char columns to ASCII characters only (e.g. throw exception when creating SQL statement)
this way you will be avoiding automatic apostrophe conversion from CHAR(700) to CHAR(39) (and maybe other similar Unicode hacks)
you always validate value length to fit actual column length (throw exception if longer)
there was a known defect in SQL Server allowing to bypass SQL error thrown on truncation (leading to silent truncation)
you ensure that SET QUOTED_IDENTIFIER is always ON
beware, it is taken into effect in parse-time, i.e. even in inaccessible sections of code
Complying with these 4 points, you should be safe. If you violate any of them, a way for SQL injection opens.
So I'm trying to wrap my head around how to combine three conflicting things (bound parameters, regex, partial-match-searching using user input) securely, and I am not sure I have discovered the right/secure way to deal with these things. This shouldn't be an uncommon concern, but the documentation that deals with the intersection of all three security factors for PDO & php is either hard to find or non-existent.
My needs are relatively simple and standard, in order of priority:
I want to prevent sql injection (currently I'm using bound
parameters)
I want to prevent regex injection
I want to search with partial matching using user input strings
So for example, I want to allow a user to search through usernames with a case insensitive partial match, e.g.
A search for Xiu will bring up the username Xiu and Xiulu and also xiuislowercase
Currently I have the following statement:
select * from users where username ilike :search_string || '%'
and elsewhere, I use more complex cases using the regex operator similarly to:
select * from users where username ~* :search_string || '%'
Where :search_string is a bound statement in php pdo, and the database is postgresql.
This performs the right search, returns the right results, and I'm reasonably certain that it is proof against sql injection since it's a bound parameter. However, I'm not certain that it is proof against regex injection, and I have no idea how to make it proof against regex injection at the same time as having it be proof against sql-injection.
How would I completely secure it against regex injection as well, using php, PDO, and postgresql?
LIKE does not support regular expressions, it only has limited pattern-matching metacharacters % and _. So if you escape those two characters with a backslash in the string before you pass it the parameter value, you should be safe.
<?php
$search_string = preg_replace('/[%_]/', '\\\\$0', $search_string);
$pdoStmt->execute(array('search_string'=>$search_string));
Alternatively, you could compare a left-substring of the username to your input, then it's comparing against a fixed string with no metacharacter pattern-matching features.
select * from users where left(username, :search_string_length) = :search_string
Re your comment:
The general rule to avoid code injection is: never execute arbitrary user input as code.
This applies to SQL injection of course, which is why we use parameters to force user input to be interpreted as values, and not modify the syntax of the SQL statement.
But it also applies to the "code" in a regular expression string within an SQL operation. A regular expression is itself a type of code logic, it's a very compact representation of a finite state machine for matching input.
The solution to avoid code injection is that it's okay to let user input choose code (as in whitelisting), but don't let the user input be interpreted as code.
I want to find rows where a text column begins with a user given string, e.g. SELECT * FROM users WHERE name LIKE 'rob%' but "rob" is unvalidated user input. If the user writes a string containing a special pattern character like "rob_", it will match both "robert42" and "rob_the_man". I need to be sure that the string is matched literally, how would I do that? Do I need to handle the escaping on an application level or is it a more beautiful way?
I'm using PostgreSQL 9.1 and go-pgsql for Go.
The _ and % characters have to be quoted to be matched literally in a LIKE statement, there's no way around it. The choice is about doing it client-side, or server-side (typically by using the SQL replace(), see below). Also to get it 100% right in the general case, there are a few things to consider.
By default, the quote character to use before _ or % is the backslash (\), but it can be changed with an ESCAPE clause immediately following the LIKE clause.
In any case, the quote character has to be repeated twice in the pattern to be matched literally as one character.
Example: ... WHERE field like 'john^%node1^^node2.uucp#%' ESCAPE '^' would match john%node1^node2.uccp# followed by anything.
There's a problem with the default choice of backslash: it's already used for other purposes when standard_conforming_strings is OFF (PG 9.1 has it ON by default, but previous versions being still in wide use, this is a point to consider).
Also if the quoting for LIKE wildcard is done client-side in a user input injection scenario, it comes in addition to to the normal string-quoting already necessary on user input.
A glance at a go-pgsql example tells that it uses $N-style placeholders for variables... So here's an attempt to write it in a somehow generic way: it works with standard_conforming_strings both ON or OFF, uses server-side replacement of [%_], an alternative quote character, quoting of the quote character, and avoids sql injection:
db.Query("SELECT * from USERS where name like replace(replace(replace($1,'^','^^'),'%','^%'),'_','^_') ||'%' ESCAPE '^'",
variable_user_input);
To escape the underscore and the percent to be used in a pattern in like expressions use the escape character:
SELECT * FROM users WHERE name LIKE replace(replace(user_input, '_', '\\_'), '%', '\\%');
As far as I can tell the only special characters with the LIKE operator is percent and underscore, and these can easily be escaped manually using backslash. It's not very beautiful but it works.
SELECT * FROM users WHERE name LIKE
regexp_replace('rob', '(%|_)', '\\\1', 'g') || '%';
I find it strange that there is no such functions shipped with PostgreSQL. Who wants their users to write their own patterns?
The best answer is that you shouldn't be interpolating user input into your sql at all. Even escaping the sql is still dangerous.
The following which uses go's db/sql library illustrates a much safer way. Substitute the Prepare and Exec calls with whatever your go postgresql library's equivalents are.
// The question mark tells the database server that we will provide
// the LIKE parameter later in the Exec call
sql := "SELECT * FROM users where name LIKE ?"
// no need to escape since this won't be interpolated into the sql string.
value := "%" + user_input
// prepare the completely safe sql string.
stmt, err := db.Prepare(sql)
// Now execute that sql with the values for every occurence of the question mark.
result, err := stmt.Exec(value)
The benefits of this are that user input can safely be used without fear of it injecting sql into the statements you run. You also get the benefit of reusing the prepared sql for multiple queries which can be more efficient in certain cases.