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In 2015, FireEye published details about two attacks exploiting
vulnerabilities in Encapsulated PostScript (EPS) of Microsoft Office.
One was a zero-day
and one was patched
weeks before the attack launched.

Recently, FireEye identified three new zero-day vulnerabilities in
Microsoft Office products that are being exploited in the wild.

At the end of March 2017, we detected another malicious document
leveraging an unknown vulnerability in EPS and a recently patched
vulnerability in Windows Graphics Device Interface (GDI) to drop
malware. Following the April 2017 Patch Tuesday, in which Microsoft
disabled EPS, FireEye detected a second unknown vulnerability in EPS.

FireEye believes that two actors – Turla
and an unknown financially motivated actor – were using the first EPS
zero-day (CVE-2017-0261),
and APT28
was using the second EPS zero-day (CVE-2017-0262)
along with a new Escalation of Privilege (EOP) zero-day (CVE-2017-0263).
Turla and APT28 are Russian cyber espionage groups that have used
these zero-days against European diplomatic and military entities. The
unidentified financial group targeted regional and global banks with
offices in the Middle East. The following is a description of the EPS
zero-days, associated malware, and the new EOP zero-day. Each EPS
zero-day is accompanied by an EOP exploit, with the EOP being required
to escape the sandbox that executes the FLTLDR.EXE instance used for
EPS processing.

The malicious documents have been used to deliver three different
payloads. CVE-2017-0261 was used to deliver SHIRIME (Turla) and
NETWIRE (unknown financially motivated actor), and CVE-2017-0262 was
used to deliver GAMEFISH (APT28). CVE-2017-0263 is used to escalate
privileges during the delivery of the GAMEFISH payload.

FireEye email
and network
products detected the malicious documents.

FireEye has been coordinating with the Microsoft Security Response
Center (MSRC) for the responsible disclosure of this information.
Microsoft advises all customers to follow the guidance in security
advisory ADV170005
as a defense-in-depth measure against EPS
filter vulnerabilities.

CVE-2017-0261 – EPS “restore” Use-After-Free

Upon opening the Office document, the FLTLDR.EXE is utilized to
render an embedded EPS image, which contains the exploit. The EPS file
is a PostScript program, which leverages a Use-After-Free
vulnerability in “restore” operand.

From the PostScript
: “Allocations in local VM and modifications to existing
objects in local VM are subject to a feature called save and
restore, named after the operators that invoke it. save
and restore bracket a section of a PostScript language program
whose local VM activity is to be encapsulated. restore
deallocates new objects and undoes modifications to existing objects
that were made since the matching save.”

As the manual described, the restore operator will reclaim
memory allocated since the save operator. This makes a perfect
condition of Use-After-Free, when combined with forall
operator. Figure 1 shows the pseudo code to exploit the save and
restore operation.

Figure 1: Pseudo code for the exploit

The following operations allow the Pseudo code to leak metadata
enabling a read/write primitive:

  1. forall_proc array is created with a single element of the
    restore proc
  2. The EPS state is
    to eps_state
  3. uaf_array is created after
    the save
  4. The forall operator loops over the elements of the
    uaf_array calling forall_proc for each element
  5. The first
    element of uaf_array is passed to a call of restore_proc, the
    procedure contained in forall_proc
  6. restore_proc

    • restores
      the initial state freeing the
    • The alloc_string procedure reclaims the freed
    • The forall_proc is updated to call
  7. Subsequent calls by the forall
    operator call the leak_proc on each element of the reclaimed
    uaf_array which elements now contain the result of the alloc_string

Figure 2 demonstrates a debug log of the uaf_array being used after
being reclaimed.

Figure 2: uaf_array reclaimed debug log

By manipulating the operations after the save operator, the
attacker is able to manipulate the memory layouts and convert the
Use-After-Free to create a read/write primitive. Figure 3 shows the
faked string, with length set as 0x7fffffff, base as 0.

Figure 3: Faked String Object

Leveraging the power of reading and writing arbitrary user memory,
the EPS program continues by searching for gadgets to build the ROP
chain, and creates a
object. Figure 4 demonstrates the faked file object
in memory.

Figure 4: Fake File Object, with ROP

By calling
operand with the faked file object, the exploit
pivots to the ROP and starts the shellcode. Figure 5 shows part of the
disassembler of
operand handler.

Figure 5: Stack Pivot disassembler of closefile

Once execution has been achieved, the malware uses the ROP chain to
change the execution protection of the memory region containing the
shellcode.  At this point, the shellcode is running within a sandbox
that was executing FLTLDR.EXE and an escalation of privilege is
required to escape that sandbox.

FireEye detected two different versions of the EPS program
exploiting this vulnerability.  The first, st07383.en17.docx,
continues by utilizing 32 or 64 bit versions of CVE-2017-0001 to
escalate privileges before executing a final JavaScript payload
containing a malware implant known as SHIRIME. SHIRIME is one of
multiple custom JavaScript implants used by Turla as a first stage
payload to conduct initial profiling of a target system and implement
command and control. Since early 2016, we have observed multiple
iterations of SHIRIME used in the wild, having the most recent version
(v1.0.1004) employed in this zero-day

The second document, Confirmation_letter.docx, continues by
utilizing 32 or 64 bit versions of CVE-2016-7255 to escalate privilege
before dropping a new variant of the NETWIRE malware family. Several
versions of this document were seen with similar filenames.

The EPS programs contained within these documents contained
different logic to perform the construction of the ROP chain as well
as build the shellcode.  The first took the additional step of using a
simple algorithm, shown in Figure 6, to obfuscate sections of the shellcode.

Figure 6: Shellcode obfuscation algorithm

CVE-2017-0262 – Type Confusion in EPS

The second EPS vulnerability is a type confused procedure object of
forall operator that can alter the execution flow allowing an attacker
to control values onto the operand stack. This vulnerability was found
in a document named “Trump’s_Attack_on_Syria_English.docx”.

Before triggering the vulnerability, the EPS program sprays the
memory with predefined data to occupy specific memory address and
facilitate the exploitation. Figure 7 demonstrates the PostScript code
snippet of spraying memory with a string.

Figure 7: PostScript code snippet of spray

After execution, the content of string occupies the memory at
address 0x0d80d000, leading to the memory layout as shown in Figure 8.
The exploit leverages this layout and the content to forge a procedure
object and manipulate the code flow to store predefined value, in
yellow, to the operator stack.

Figure 8: Memory layout of the sprayed data

After spraying the heap, the exploit goes on to call a code
statement in the following format: 1 array 16#D80D020 forall.
It creates an Array object, sets the procedure as the hex number
0xD80D020, and calls the forall operator. During the operation
of the forged procedure within forall operator, it precisely
controls the execution flow to store values of the attacker’s choices
to operand stack. Figure 9 shows the major code flow consuming the
forged procedure.

Figure 9: Consuming the forged procedure

After execution of forall, the contents on the stack are
under the attacker’s control. This is s shown in Figure 10.

Figure 10: Stack after the forall execution

Since the operand stack has been manipulated, the subsequent
operations of exch defines objects based on the data from the
manipulated stack, as shown in Figure 11.

Figure 11: Subsequent code to retrieve data from stack

The A18 is a string type object, which has a length field of
0x7ffffff0, based from 0. Within memory, the layout as shown in Figure 12.

Figure 12: A18 String Object

The A19 is an array type object, with member values all purposely
crafted. The exploit defines another array object and puts it into the
forged array A19. By performing these operations, it puts the newly
created array object pointer into A19. The exploit can then directly
read the value from the predictable address, 0xD80D020 + 0x38, and
leak its vftable and infer module base address of EPSIMP32.flt. Figure
13 shows code snippets of leaking EPSIMP32 base address.

Figure 13: Code snippet of leaking module base

Figure 14 shows the operand stack of calling put operator and
the forged Array A19 after finishing the put operation.

Figure 14: Array A19 after the put operation

By leveraging the RW primitive string and the leaked module base of
EPSIMP32, the exploit continues by searching ROP gadgets, creating a
fake file object, and pivoting to shellcode through the
bytesavailable operator. Figure 15 shows the forged file type
object and disassembling of pivoting to ROP and shellcode.

Figure 15: Pivots to ROP and Shellcode

The shellcode continues by using a previously unknown EOP,
CVE-2017-0263, to escalate privileges to escape the sandbox running
FLTLDR.EXE, and then drop and execute a GAMEFISH payload. Only a
32-bit version of CVE-2017-0263 is contained in the shellcode.

CVE-2017-0263 – win32k!xxxDestroyWindow Use-After-Free

The EOP Exploit setup starts by suspending all threads other than
the current thread and saving the thread handles to a table, as shown
in Figure 16.

Figure 16: Suspending Threads

The exploit then checks for OS version and uses that information to
populate version specific fields such as token offset, syscall number,
etc. An executable memory area is allocated and populated with kernel
mode shellcode as wells as address information required by the
shellcode. A new thread is created for triggering the vulnerability
and further control of exploitation.

The exploit starts by creating three PopupMenus and appending menus
to them, as shown in Figure 17. The exploit creates 0x100 windows with
random classnames. The User32!HMValidateHandle trick is used to leak
the tagWnd address, which is used as kernel information leak
throughout the exploit.

Figure 17: Popup menu creation

RegisterClassExW is then used to register a window class
“Main_Window_Class” with a WndProc pointing to a function, which calls
DestroyWindow on window table created by EventHookProc, explained
later in the blog. This function also shows the first popup menu,
which was created earlier.

Two extra windows are created with class name as
“Main_Window_Class”. SetWindowLong is used to change WndProc of second
window, wnd2, to a shellcode address. An application defined hook,
WindowHookProc, and an event hook, EventHookProc, are installed by
SetWindowsHookExW and SetWinEventHook respectively. PostMessage is
used to post 0xABCD to first window, wnd1.

The EventHookProc waits for EVENT_SYSTEM_MENUPOPUPSTART and saves
the window’s handle to a table. WindowHookProc looks for SysShadow
classname and sets a new WndProc for the corresponding window.
Inside this WndProc, NtUserMNDragLeave syscall is invoked and
SendMessage is used to send 0x9f9f to wnd2, invoking the shellcode
shown in Figure 18.

Figure 18: Triggering the shellcode

The Use-After-Free happens inside WM_NCDESTROY event in kernel and
overwrites wnd2’s tagWnd structure, which sets bServerSideWindowProc
flag. With bServerSideWindowProc set, the user mode WndProc is
considered as a kernel callback and will be invoked from kernel
context – in this case wnd2’s WndProc is the shellcode.

The shellcode checks whether the memory corruption has occurred by
checking if the code segment is not the user mode code segment. It
also checks whether the message sent is 0x9f9f. Once the validation is
completed, shellcode finds the TOKEN address of current process and
TOKEN of system process (pid 4). The shellcode then copies the system
process’ token to current process, which elevates current process
privilege to SYSTEM.


EPS processing has become a ripe exploitation space for attackers.

FireEye has discovered and analyzed two of these recent EPS
zero-days with examples seen before and after Microsoft disabled EPS
processing in the April 2017 Patch Tuesday.  The documents explored
utilize differing EPS exploits, ROP construction, shellcode, EOP
exploits and final payloads. While these documents are detected by
FireEye appliances, users should exercise caution because FLTLDR.EXE
is not monitored by EMET.

Russian cyber espionage is a well-resourced, dynamic threat

The use of zero-day exploits by Turla Group and APT28 underscores
their capacity to apply technically sophisticated and costly methods
when necessary. Russian cyber espionage actors use zero-day exploits
in addition to less complex measures. Though these actors have relied
on credential phishing and macros to carry out operations previously,
the use of these methods does not reflect a lack of resources. Rather,
the use of less technically sophisticated methods – when sufficient –
reflects operational maturity and the foresight to protect costly
exploits until they are necessary.

A vibrant ecosystem of threats

CVE-2017-0261’s use by multiple actors is further evidence that
cyber espionage and criminal activity exist in a shared ecosystem.
Nation state actors, such as those leveraging CVE-2017-0199
to distribute FINSPY
, often rely on the same sources for
exploits as criminal actors. This shared ecosystem creates a
proliferation problem for defenders concerned with either type of threat.

CVE-2017-0261 was being used as a zero-day by both nation state and
cyber crime actors, and we believe that both actors obtained the
vulnerability from a common source. Following CVE-2017-0199,
this is the second major vulnerability in as many months that has been
used for both espionage and crime.



C2 Host
















Table 1: Source Exploit Documents

Table 2: CVEs related to these attacks


iSIGHT Intelligence Team, FLARE Team, FireEye Labs, Microsoft
Security Response Center (MSRC).

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