F1vm 32 Bit | 2026 Release |

dd if=f1vm_32bit of=bytecode.bin bs=1 skip=$((0x804B040)) count=256 Using xxd :

00000000: 01 01 00 00 00 40 mov reg1, 0x40000000 00000006: 10 01 push reg1 ... At offset 0x80 inside the bytecode, there’s a sequence:

import struct mem = bytearray(open('bytecode.bin', 'rb').read()) reg = [0]*8 stack = [] pc = 0 f1vm 32 bit

enc = bytes.fromhex("25 73 12 45 9A 34 22 11 ...") key = 0xDEADBEEF flag = '' for i, b in enumerate(enc): shift = (i * 8) % 32 key_byte = (key >> shift) & 0xFF flag += chr(b ^ key_byte) print(flag) Output:

while True: op = mem[pc] pc += 1 if op == 0x01: # MOV reg, imm r = mem[pc]; pc += 1 imm = struct.unpack('<I', mem[pc:pc+4])[0]; pc += 4 reg[r] = imm elif op == 0x02: # ADD src = mem[pc]; dst = mem[pc+1]; pc += 2 reg[dst] += reg[src] elif op == 0x03: # XOR src = mem[pc]; dst = mem[pc+1]; pc += 2 reg[dst] ^= reg[src] elif op == 0x10: # PUSH r = mem[pc]; pc += 1 stack.append(reg[r]) elif op == 0xFF: break # ... other ops dd if=f1vm_32bit of=bytecode

The VM initializes reg0 as the bytecode length, reg1 as the starting address of encrypted flag. The flag is likely embedded as encrypted bytes in the VM’s memory[] . In the binary, locate the .rodata section – there’s a 512-byte chunk starting at 0x804B040 containing the bytecode + encrypted data.

Run the binary:

while (1) opcode = memory[pc++]; switch(opcode) case 0x01: // MOV reg, imm case 0x02: // ADD case 0x03: // XOR ...