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EEYE: Microsoft ASN.1 Library Length Overflow Heap Corruption



Microsoft ASN.1 Library Length Overflow Heap Corruption

Release Date:
February 10, 2004

Date Reported:
July 25, 2003

Severity:
High (Remote Code Execution)

Systems Affected:
Microsoft Windows NT 4.0 (all versions)
Microsoft Windows 2000 (SP3 and earlier)
Microsoft Windows XP (all versions)

Software Affected:
Microsoft Internet Explorer
Microsoft Outlook
Microsoft Outlook Express
Third-party applications that use certificates

Services Affected:
Kerberos (UDP/88)
Microsoft IIS using SSL
NTLMv2 authentication (TCP/135, 139, 445)

Preamble:

We wanted to do another Night Before Xmas but the vendor missed the last
few release dates, so we had to resort to our MC(SE).

U Can't Trust This
By: MCSE Hammer

Blaster did ya some harm
We just say, hey, another worm
But thank you, for trusting me
To mind your site's security
It's all good, when your server's downed
Our dope PR will pass blame around
Cuz it's known as such
That this is some software, you can't trust

I told ya Homeland
U can't trust this
Yeah that's why we're giving ya the code
U can't trust this
Check out eEye, man
U can't trust this
Yo let 'em bust more funky system
U can't trust this

Give 'em a string or recvfrom
Like no sweat they got the keys to your kingdom
Now ya know
You talk about eEye, you're talking about holes
Remote and tight
Coders still sweating so someone better write
A book to learn
What it's gonna take in '04
To earn some trust
Legit, either secure or ya might as well quit

That's the word because you know
U can't trust this
U can't trust this

Breakin' in

Stop -- eEye time

Description:
eEye Digital Security has discovered a critical vulnerability in
Microsoft's ASN.1 library (MSASN1.DLL) that would allow an attacker to
overwrite heap memory on a susceptible machine and cause the execution
of arbitrary code.  Because this library is widely used by Windows
security subsystems, the vulnerability is exposed through an array of
avenues, including Kerberos, NTLMv2 authentication, and applications
that make use of certificates (SSL, digitally-signed e-mail, signed
ActiveX controls, etc.).

Technical Description:
The MSASN1 library is fraught with integer overflows.  In this advisory,
we'll describe a pair of arithmetic errors in a generic and low-level
part of ASN.1 BER decoding that allow a very large swath of heap memory
to be overwritten.  This vulnerability affects basically any client of
MSASN1.DLL, the most interesting of which are LSASS.EXE and CRYPT32.DLL
(and therefore any application that uses CRYPT32.DLL).

Although the specifics of ASN.1 BER encoding are beyond the scope of
this advisory, the basic idea is that it's an encoding scheme for
flexibly representing binary data, and is often compared to "binary
XML."  Each piece of data is encoded as a typed value, which is
constructed as a tag number that describes how to interpret the
following value data, then the length of the data, and finally, the data
itself.  This length field is the subject of our advisory.  By supplying
a very large value (from 0xFFFFFFFD to 0xFFFFFFFF) in this field, we can
cause an integer overflow in a heap allocation routine, and although
there are checks in place to ensure the validity of a value's length, a
separate pointer arithmetic overflow in the verification routine gives
rise to the vulnerability.  Here's how:

1. When a simple value (a value that consists of atomic data, rather
than more values) is decoded by MSASN1, ASN1BERDecLength() is called to
retrieve the length of the value, then passes the reported length to the
ASN1BERDecCheck() function to make sure that that much data actually
exists.

2. ASN1BERDecCheck() verifies that (pointer_to_start_of_data +
reported_length_of_data), unsigned, is less than or equal to
(pointer_to_start_of_BER_block + total_size_of_BER_block).  If not, the
function returns failure, which propagates back up the call stack and
causes decoding to stop.  (As an aside, it's interesting to note that
this vulnerability was silently fixed in Windows 2000 SP4 and Windows
Server 2003, due to an additional comparison being included in
ASN1BERDecCheck().)

3. If the function that called ASN1BERDecLength() then attempts to
allocate memory and make a copy of the data (e.g.,
ASN1BERDecOctetString(), but not the ASN1BERDecOctetString2() variant),
it will then pass the decoded length to DecMemAlloc(), which rounds the
length up to a DWORD multiple and then attempts to allocate the result.
The operation of this function can be represented as
"LocalAlloc(LMEM_ZEROINIT, (length + 3) & ~3)."

4. If DecMemAlloc() succeeds, the calling function then memcpy()'s the
value data into the allocated heap buffer, using the original decoded
length of the value as the byte count.

If a very large length is decoded by ASN1BERDecLength() in step 1, then
there will be an integer overflow when ASN1BERDecCheck() adds the length
to the current data pointer in step 2, essentially causing the resulting
pointer to "wrap around" the 32-bit address space and therefore have an
address that is numerically less than the pointer to the end of the
buffer.

Now, to be more specific, if a length in the range 0xFFFFFFFD through
0xFFFFFFFF is given, it will pass through ASN1BERDecCheck() with no
problem, and then something really bad happens.  Because of the
round-off in DecMemAlloc(), the three lengths in this range will all
round "up" to zero.  LocalAlloc() successfully allocates a zero-length
heap block whose address gets returned to the caller, but then the
original, very large length is handed to memcpy().  The result is a
classic, complete heap overwrite, where all contiguous heap memory
following the zero-length block is wiped out by arbitrary data.

The simplest way to manifest this condition is to encode a simple octet
string (tag 04h) with a length-of-length set to 4 and a length of
0xFFFFFFFF, which corresponds to the bytes 04h/84h/FFh/FFh/FFh/FFh.
Depending on which decoder functions the MSASN1 client uses, it is also
possible to leverage this vulnerability through OIDs and character
strings as well.  The following is a sampling of vulnerable decoder
functions:

ASN1BerDecCharString
ASN1BERDecChar16String
ASN1BERDecChar32String
ASN1BERDecEoid
ASN1BERDecGeneralizedTime
ASN1BERDecMultibyteString
ASN1BERDecOctetString
ASN1BERDecOpenType
ASN1BERDecSXVal
ASN1BERDecUTCTime
ASN1BERDecUTF8String
ASN1BERDecZeroCharString
ASN1BERDecZeroChar16String
ASN1BERDecZeroChar32String
ASN1BERDecZeroMultibyteString

Note: Due to the technical nature of the vulnerability described above,
this advisory may contain disassembly and/or hexadecimal byte codes.
This information is in no way related to "exploit code", "payloads", or
"shell code".

Protection:
Retina Network Security Scanner has been updated to identify this
vulnerability:
http://www.eeye.com/html/Products/Retina/index.html

Vendor Status:
Microsoft has released a patch for this vulnerability. The patch is
available at:
http://www.microsoft.com/technet/security/bulletin/MS04-007.asp

Credit:
Discovery: Derek Soeder
Additional Research: Yuji Ukai

Very Special Thanks:
Yuji Ukai, again, for the majority of "The Menu"
Steve Peters and Shawn O'Donnell for extreme ASN.1 (BER!) and
certificate lore

Greetings:
DDDDDD; GM-TX, BMNN-FL, JKP-FL, NV-TX; Heather & Heather; all the coffee
shop folks; 214; and always, every last one of the eEye crew

Copyright (c) 1998-2004 eEye Digital Security
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