=========================== Indexed blind SQL injection ===========================
:Author: gamma95 <gamma95 [at] gmail> and his minions
:Date: December 03, 2011
Time based blind SQL attack suffers from low bit/request ratio. Each request
produces only one valuable bit of information. This paper describes a tweak
that produces higher yield at the expense of longer runtime. Along the way,
some issues and notes of applicability are also discussed.
Background
++++++++++
Time based blind SQL injection attack is probably the most well-known technique
in the planet. The method works by analyzing the time difference in various
queries. Because query execution time is a side effect of a query, no visible
output is required for this method to succeed. For example, a query could
request that the DBMS to sleep for 10 seconds if the first character of the
username is ``A``.
Usually, time based technique go hand in hand with binary search. Instead of
asking if the first character is ``1``, then ``2``, then ``3``, it could
partition the possible values into two ranges (say from ``0`` to ``4`` and
``5`` to ``9``) and ask if the first character is less than ``5``. Depending on
the result, it picks out the more likely range and repeats the process until
there is only one possible value. This effectively puts a logarithmic bound on
number of requests to the DBMS.
In other words, each request gives us one bit of information.
Increasing the usable bit/request ratio
+++++++++++++++++++++++++++++++++++++++
Due to low bit/request ratio, an attack attempt usually leaves behind too many
requests in access log. This is undesirable.
A better approach could be to encode the correct value into query execution
time itself. For example, if we know the value is a number from 0 to 9, we
could ask DBMS to sleep for that many seconds straight. In this case, one
request carries more than 3 bits of usable information.
This is the principal idea behind our tweak.
Indexed time based attack
+++++++++++++++++++++++++
To encode more bits into the execution time, we must work with variable numeric
delay values. Therefore, we need two things:
+ A measurable delay interval. Too short the interval and network latency
could negatively affect our measurement. Too long the delay will also waste our
time.
+ And its mapping to target values. A delay of one second could mean
character ``A`` or it could also mean some other value, depending on the
possible domain.
These necessitate an array-like index search. Say, if our domain is ten
(character) values from ``0`` to ``9``, then we can easily combine them into an
array like shown below.
::
1 2 3 4 5 6 7 8 9 10 (index)
| | | | | | | | | |
v v v v v v v v v v
+---+---+---+---+---+---+---+---+---+---+
| 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | (value)
+---+---+---+---+---+---+---+---+---+---+
Given a random character, we can tell in one request if it is in this set, and
if it is, what specific character it actually is. The way to do that is by
delaying query time by the index of the character. If the input character is
not in the set, there will be no delay. If it is, its index is determinable
from the sleep time.
An example
++++++++++
Suppose we are trying to grab version information from a **MySQL** server.
Possible characters include 0-9 and period. Observe the execution time.
::
select sleep(find_in_set(mid(@@version, 1, 1), '0,1,2,3,4,5,6,7,8,9,.'));
1 row in set (6.04 sec)
# index 6, value '5'
select sleep(find_in_set(mid(@@version, 2, 1), '0,1,2,3,4,5,6,7,8,9,.'));
1 row in set (11.00 sec)
# index 11, value '.'
select sleep(find_in_set(mid(@@version, 3, 1), '0,1,2,3,4,5,6,7,8,9,.'));
1 row in set (2.00 sec)
# index 2, value '1'
...
Each request gives us exactly one character (not bit).
Notes of applicability
++++++++++++++++++++++
Adjusting sleep time
====================
Faster sleep time is easily achievable by multiplying the index with some
factor smaller than 1. For example, we can sleep half the time as before::
select sleep(0.5 * find_in_set(mid(@@version, 1, 1),
'0,1,2,3,4,5,6,7,8,9,.'));
1 row in set (3.00 sec)
# index 6, value '5'
Similarly, longer sleep time can use factors greater than 1.
Guarding against network latency
================================
Time based attack generally works best in a fast and reliable networked
environment. Small jitters in latency could skew the measurements and affect
end result. However, this technique we are describing here could be modified to
support network latency.
The idea is that since sleeping time is a calculated number, we could add to it
a fixed amount of time for latency, or prepend some invalid characters (such as
``a`` when the domain is 0-9) in the domain set.
::
select sleep(find_in_set(mid(@@version, 1, 1),
'a,a,a,a,0,1,2,3,4,5,6,7,8,9,.'));
1 row in set (10.00 sec)
# index 10, value '5'
We can also sprinkle invalid characters in between valid characters to manually
adjust amount of sleeping time.
Picking an acceptable domain
============================
The set of possible values should be carefully picked to match the value that
one expects. Wide domain (more values) has a better chance of catching the
input, but it requires a longer sleep time on average. Narrow domain (less
values) has slimmer chance to catch the input, but it generally finishes faster
on average.
Some web frameworks enforce a maximum execution time. A query that takes more
than, say, 30 seconds will be prime target for an early termination (and
possibly logging). Therefore, picking out an acceptable domain is not only an
optimization but sometimes a necessity.
Using other functions
=====================
``find_in_set`` is only one of the string search functions that MySQL supports.
One can also use other functions such as ``instr``, ``locate``, and
``position``.
Sleeping in ``WHERE`` clause
============================
Most of the time, the injection point is in a ``WHERE`` clause. Because the
``WHERE`` clause is tested against all candidate rows, we better make sure that
there is only **one** candidate. We can do that by making sure the table scan
produces one row. Otherwise, our sleep measure will be multiplied up by the
number of candidates.
::
create table test (a int primary key, b char(16));
insert into test values(1, 'abcd');
insert into test values(2, 'zyxw');
select count(*) from test;
+----------+
| count(*) |
+----------+
| 2 |
+----------+
# we have 2 rows in table test
select * from test where sleep(locate(mid(@@version, 1, 1), '0123456789.'));
Empty set (12.00 sec)
# here we sleep for 12 seconds because all (2) rows are tested
select * from test where a=1 and sleep(locate(mid(@@version, 1, 1),
'0123456789.'));
Empty set (6.00 sec)
# here we sleep for 6 seconds because only one row is tested
Conclusion
++++++++++
This paper described a small tweak to the well-known time based SQL injection
technique. The principle behind the increase in bit/request ratio is encoding
more information in the query execution time. This is done with index based
array search functions such as ``find_in_set``. The desirably smaller number of
requests comes at the expense of generally longer execution time.
This paper also discussed about some technical concerns that one must pay close
attention to when employing the technique. Minute aspects such as table scan,
applicable value domain, network latency, and amount of sleep time are at the
top list to watch out for.
Acknowledgement
+++++++++++++++
Thanks go to Nam Nguyen for his early review and support.
--
Nam Nguyen, CISA, CISSP, CSSLP
Blue Moon Consulting Co., Ltd
http://www.bluemoon.com.vn
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