/* Java bindings for the Unicorn Emulator Engine Copyright(c) 2015 Chris Eagle This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License version 2 as published by the Free Software Foundation. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ /* Unicorn Emulator Engine */ /* By Nguyen Anh Quynh & Dang Hoang Vu, 2015 */ /* Sample code to demonstrate how to emulate X86 code */ import unicorn.*; public class Sample_x86 { // code to be emulated public static final byte[] X86_CODE32 = {65,74}; public static final byte[] X86_CODE32_JUMP = {-21,2,-112,-112,-112,-112,-112,-112}; public static final byte[] X86_CODE32_SELF = {-21,28,90,-119,-42,-117,2,102,61,-54,125,117,6,102,5,3,3,-119,2,-2,-62,61,65,65,65,65,117,-23,-1,-26,-24,-33,-1,-1,-1,49,-46,106,11,88,-103,82,104,47,47,115,104,104,47,98,105,110,-119,-29,82,83,-119,-31,-54,125,65,65,65,65}; public static final byte[] X86_CODE32_LOOP = {65,74,-21,-2}; public static final byte[] X86_CODE32_MEM_WRITE = {-119,13,-86,-86,-86,-86,65,74}; public static final byte[] X86_CODE32_MEM_READ = {-117,13,-86,-86,-86,-86,65,74}; public static final byte[] X86_CODE32_JMP_INVALID = {-23,-23,-18,-18,-18,65,74}; public static final byte[] X86_CODE32_INOUT = {65,-28,63,74,-26,70,67}; public static final byte[] X86_CODE64 = {65,-68,59,-80,40,42,73,15,-55,-112,77,15,-83,-49,73,-121,-3,-112,72,-127,-46,-118,-50,119,53,72,-9,-39,77,41,-12,73,-127,-55,-10,-118,-58,83,77,-121,-19,72,15,-83,-46,73,-9,-44,72,-9,-31,77,25,-59,77,-119,-59,72,-9,-42,65,-72,79,-115,107,89,77,-121,-48,104,106,30,9,60,89}; public static final byte[] X86_CODE16 = {0, 0}; // add byte ptr [bx + si], al // memory address where emulation starts public static final int ADDRESS = 0x1000000; public static final long toInt(byte val[]) { long res = 0; for (int i = 0; i < val.length; i++) { long v = val[i] & 0xff; res = res + (v << (i * 8)); } return res; } public static final byte[] toBytes(long val) { byte[] res = new byte[8]; for (int i = 0; i < 8; i++) { res[i] = (byte)(val & 0xff); val >>>= 8; } return res; } // callback for tracing basic blocks // callback for tracing instruction private static class MyBlockHook implements BlockHook { public void hook(Unicorn u, long address, int size, Object user_data) { System.out.printf(">>> Tracing basic block at 0x%x, block size = 0x%x\n", address, size); } } // callback for tracing instruction private static class MyCodeHook implements CodeHook { public void hook(Unicorn u, long address, int size, Object user_data) { System.out.printf(">>> Tracing instruction at 0x%x, instruction size = 0x%x\n", address, size); byte eflags[] = u.reg_read(Unicorn.UC_X86_REG_EFLAGS, 4); System.out.printf(">>> --- EFLAGS is 0x%x\n", toInt(eflags)); // Uncomment below code to stop the emulation using uc_emu_stop() // if (address == 0x1000009) // u.emu_stop(); } } private static class MyWriteInvalidHook implements EventMemHook { public boolean hook(Unicorn u, long address, int size, long value, Object user) { System.out.printf(">>> Missing memory is being WRITE at 0x%x, data size = %d, data value = 0x%x\n", address, size, value); // map this memory in with 2MB in size u.mem_map(0xaaaa0000, 2 * 1024*1024, Unicorn.UC_PROT_ALL); // return true to indicate we want to continue return true; } } // callback for tracing instruction private static class MyCode64Hook implements CodeHook { public void hook(Unicorn u, long address, int size, Object user_data) { byte[] r_rip = u.reg_read(Unicorn.UC_X86_REG_RIP, 8); System.out.printf(">>> Tracing instruction at 0x%x, instruction size = 0x%x\n", address, size); System.out.printf(">>> RIP is 0x%x\n", toInt(r_rip)); // Uncomment below code to stop the emulation using uc_emu_stop() // if (address == 0x1000009) // uc_emu_stop(handle); } } private static class MyRead64Hook implements ReadHook { public void hook(Unicorn u, long address, int size, Object user) { System.out.printf(">>> Memory is being READ at 0x%x, data size = %d\n", address, size); } } private static class MyWrite64Hook implements WriteHook { public void hook(Unicorn u, long address, int size, long value, Object user) { System.out.printf(">>> Memory is being WRITE at 0x%x, data size = %d, data value = 0x%x\n", address, size, value); } } // callback for IN instruction (X86). // this returns the data read from the port private static class MyInHook implements InHook { public int hook(Unicorn u, int port, int size, Object user_data) { byte[] r_eip = u.reg_read(Unicorn.UC_X86_REG_EIP, 4); System.out.printf("--- reading from port 0x%x, size: %d, address: 0x%x\n", port, size, toInt(r_eip)); switch(size) { case 1: // read 1 byte to AL return 0xf1; case 2: // read 2 byte to AX return 0xf2; case 4: // read 4 byte to EAX return 0xf4; } return 0; } } // callback for OUT instruction (X86). private static class MyOutHook implements OutHook { public void hook(Unicorn u, int port, int size, int value, Object user) { byte[] eip = u.reg_read(Unicorn.UC_X86_REG_EIP, 4); byte[] tmp = null; System.out.printf("--- writing to port 0x%x, size: %d, value: 0x%x, address: 0x%x\n", port, size, value, toInt(eip)); // confirm that value is indeed the value of AL/AX/EAX switch(size) { default: return; // should never reach this case 1: tmp = u.reg_read(Unicorn.UC_X86_REG_AL, 1); break; case 2: tmp = u.reg_read(Unicorn.UC_X86_REG_AX, 2); break; case 4: tmp = u.reg_read(Unicorn.UC_X86_REG_EAX, 4); break; } System.out.printf("--- register value = 0x%x\n", toInt(tmp)); } } static void test_i386() { byte r_ecx[] = {(byte)0x34, (byte)0x12, 0, 0}; //0x1234; // ECX register byte r_edx[] = {(byte)0x90, (byte)0x78, 0, 0}; //0x7890; // EDX register System.out.print("Emulate i386 code\n"); // Initialize emulator in X86-32bit mode Unicorn uc; try { uc = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_32); } catch (UnicornException uex) { System.out.println("Failed on uc_open() with error returned: " + uex); return; } // map 2MB memory for this emulation uc.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory try { uc.mem_write(ADDRESS, X86_CODE32); } catch (UnicornException uex) { System.out.println("Failed to write emulation code to memory, quit!\n"); return; } // initialize machine registers uc.reg_write(Unicorn.UC_X86_REG_ECX, r_ecx); uc.reg_write(Unicorn.UC_X86_REG_EDX, r_edx); // tracing all basic blocks with customized callback uc.hook_add(new MyBlockHook(), 1, 0, null); // tracing all instruction by having @begin > @end uc.hook_add(new MyCodeHook(), 1, 0, null); // emulate machine code in infinite time try { uc.emu_start(ADDRESS, ADDRESS + X86_CODE32.length, 0, 0); } catch (UnicornException uex) { System.out.printf("Failed on uc_emu_start() with error : %s\n", uex.getMessage()); } // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); r_ecx = uc.reg_read(Unicorn.UC_X86_REG_ECX, 4); r_edx = uc.reg_read(Unicorn.UC_X86_REG_EDX, 4); System.out.printf(">>> ECX = 0x%x\n", toInt(r_ecx)); System.out.printf(">>> EDX = 0x%x\n", toInt(r_edx)); // read from memory try { byte tmp[] = uc.mem_read(ADDRESS, 4); System.out.printf(">>> Read 4 bytes from [0x%x] = 0x%x\n", ADDRESS, toInt(tmp)); } catch (UnicornException ex) { System.out.printf(">>> Failed to read 4 bytes from [0x%x]\n", ADDRESS); } uc.close(); } static void test_i386_inout() { byte[] r_eax = {0x34, 0x12, 0, 0}; //0x1234; // EAX register byte[] r_ecx = {(byte)0x89, 0x67, 0, 0}; //0x6789; // ECX register System.out.print("===================================\n"); System.out.print("Emulate i386 code with IN/OUT instructions\n"); // Initialize emulator in X86-32bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_32); // map 2MB memory for this emulation u.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(ADDRESS, X86_CODE32_INOUT); // initialize machine registers u.reg_write(Unicorn.UC_X86_REG_EAX, r_eax); u.reg_write(Unicorn.UC_X86_REG_ECX, r_ecx); // tracing all basic blocks with customized callback u.hook_add(new MyBlockHook(), 1, 0, null); // tracing all instructions u.hook_add(new MyCodeHook(), 1, 0, null); // handle IN instruction u.hook_add(new MyInHook(), null); // handle OUT instruction u.hook_add(new MyOutHook(), null); // emulate machine code in infinite time u.emu_start(ADDRESS, ADDRESS + X86_CODE32_INOUT.length, 0, 0); // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); r_eax = u.reg_read(Unicorn.UC_X86_REG_EAX, 4); r_ecx = u.reg_read(Unicorn.UC_X86_REG_ECX, 4); System.out.printf(">>> EAX = 0x%x\n", toInt(r_eax)); System.out.printf(">>> ECX = 0x%x\n", toInt(r_ecx)); u.close(); } static void test_i386_jump() { System.out.print("===================================\n"); System.out.print("Emulate i386 code with jump\n"); // Initialize emulator in X86-32bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_32); // map 2MB memory for this emulation u.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(ADDRESS, X86_CODE32_JUMP); // tracing 1 basic block with customized callback u.hook_add(new MyBlockHook(), ADDRESS, ADDRESS, null); // tracing 1 instruction at ADDRESS u.hook_add(new MyCodeHook(), ADDRESS, ADDRESS, null); // emulate machine code in infinite time u.emu_start(ADDRESS, ADDRESS + X86_CODE32_JUMP.length, 0, 0); System.out.print(">>> Emulation done. Below is the CPU context\n"); u.close(); } // emulate code that loop forever static void test_i386_loop() { byte r_ecx[] = {(byte)0x34, (byte)0x12, 0, 0}; //0x1234; // ECX register byte r_edx[] = {(byte)0x90, (byte)0x78, 0, 0}; //0x7890; // EDX register System.out.print("===================================\n"); System.out.print("Emulate i386 code that loop forever\n"); // Initialize emulator in X86-32bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_32); // map 2MB memory for this emulation u.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(ADDRESS, X86_CODE32_LOOP); // initialize machine registers u.reg_write(Unicorn.UC_X86_REG_ECX, r_ecx); u.reg_write(Unicorn.UC_X86_REG_EDX, r_edx); // emulate machine code in 2 seconds, so we can quit even // if the code loops u.emu_start(ADDRESS, ADDRESS + X86_CODE32_LOOP.length, 2 * Unicorn.UC_SECOND_SCALE, 0); // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); r_ecx = u.reg_read(Unicorn.UC_X86_REG_ECX, 4); r_edx = u.reg_read(Unicorn.UC_X86_REG_EDX, 4); System.out.printf(">>> ECX = 0x%x\n", toInt(r_ecx)); System.out.printf(">>> EDX = 0x%x\n", toInt(r_edx)); u.close(); } // emulate code that read invalid memory static void test_i386_invalid_mem_read() { byte r_ecx[] = {(byte)0x34, (byte)0x12, 0, 0}; //0x1234; // ECX register byte r_edx[] = {(byte)0x90, (byte)0x78, 0, 0}; //0x7890; // EDX register System.out.print("===================================\n"); System.out.print("Emulate i386 code that read from invalid memory\n"); // Initialize emulator in X86-32bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_32); // map 2MB memory for this emulation u.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(ADDRESS, X86_CODE32_MEM_READ); // initialize machine registers u.reg_write(Unicorn.UC_X86_REG_ECX, r_ecx); u.reg_write(Unicorn.UC_X86_REG_EDX, r_edx); // tracing all basic blocks with customized callback u.hook_add(new MyBlockHook(), 1, 0, null); // tracing all instruction by having @begin > @end u.hook_add(new MyCodeHook(), 1, 0, null); // emulate machine code in infinite time try { u.emu_start(ADDRESS, ADDRESS + X86_CODE32_MEM_READ.length, 0, 0); } catch (UnicornException uex) { int err = u.errno(); System.out.printf("Failed on u.emu_start() with error returned: %s\n", uex.getMessage()); } // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); r_ecx = u.reg_read(Unicorn.UC_X86_REG_ECX, 4); r_edx = u.reg_read(Unicorn.UC_X86_REG_EDX, 4); System.out.printf(">>> ECX = 0x%x\n", toInt(r_ecx)); System.out.printf(">>> EDX = 0x%x\n", toInt(r_edx)); u.close(); } // emulate code that read invalid memory static void test_i386_invalid_mem_write() { byte r_ecx[] = {(byte)0x34, (byte)0x12, 0, 0}; //0x1234; // ECX register byte r_edx[] = {(byte)0x90, (byte)0x78, 0, 0}; //0x7890; // EDX register System.out.print("===================================\n"); System.out.print("Emulate i386 code that write to invalid memory\n"); // Initialize emulator in X86-32bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_32); // map 2MB memory for this emulation u.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(ADDRESS, X86_CODE32_MEM_WRITE); // initialize machine registers u.reg_write(Unicorn.UC_X86_REG_ECX, r_ecx); u.reg_write(Unicorn.UC_X86_REG_EDX, r_edx); // tracing all basic blocks with customized callback u.hook_add(new MyBlockHook(), 1, 0, null); // tracing all instruction by having @begin > @end u.hook_add(new MyCodeHook(), 1, 0, null); // intercept invalid memory events u.hook_add(new MyWriteInvalidHook(), Unicorn.UC_HOOK_MEM_WRITE_UNMAPPED, null); // emulate machine code in infinite time try { u.emu_start(ADDRESS, ADDRESS + X86_CODE32_MEM_WRITE.length, 0, 0); } catch (UnicornException uex) { System.out.printf("Failed on uc_emu_start() with error returned: %s\n", uex.getMessage()); } // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); r_ecx = u.reg_read(Unicorn.UC_X86_REG_ECX, 4); r_edx = u.reg_read(Unicorn.UC_X86_REG_EDX, 4); System.out.printf(">>> ECX = 0x%x\n", toInt(r_ecx)); System.out.printf(">>> EDX = 0x%x\n", toInt(r_edx)); // read from memory byte tmp[] = u.mem_read(0xaaaaaaaa, 4); System.out.printf(">>> Read 4 bytes from [0x%x] = 0x%x\n", 0xaaaaaaaa, toInt(tmp)); try { u.mem_read(0xffffffaa, 4); System.out.printf(">>> Read 4 bytes from [0x%x] = 0x%x\n", 0xffffffaa, toInt(tmp)); } catch (UnicornException uex) { System.out.printf(">>> Failed to read 4 bytes from [0x%x]\n", 0xffffffaa); } u.close(); } // emulate code that jump to invalid memory static void test_i386_jump_invalid() { byte r_ecx[] = {(byte)0x34, (byte)0x12, 0, 0}; //0x1234; // ECX register byte r_edx[] = {(byte)0x90, (byte)0x78, 0, 0}; //0x7890; // EDX register System.out.print("===================================\n"); System.out.print("Emulate i386 code that jumps to invalid memory\n"); // Initialize emulator in X86-32bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_32); // map 2MB memory for this emulation u.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(ADDRESS, X86_CODE32_JMP_INVALID); // initialize machine registers u.reg_write(Unicorn.UC_X86_REG_ECX, r_ecx); u.reg_write(Unicorn.UC_X86_REG_EDX, r_edx); // tracing all basic blocks with customized callback u.hook_add(new MyBlockHook(), 1, 0, null); // tracing all instructions by having @begin > @end u.hook_add(new MyCodeHook(), 1, 0, null); // emulate machine code in infinite time try { u.emu_start(ADDRESS, ADDRESS + X86_CODE32_JMP_INVALID.length, 0, 0); } catch (UnicornException uex) { System.out.printf("Failed on uc_emu_start() with error returned: %s\n", uex.getMessage()); } // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); r_ecx = u.reg_read(Unicorn.UC_X86_REG_ECX, 4); r_edx = u.reg_read(Unicorn.UC_X86_REG_EDX, 4); System.out.printf(">>> ECX = 0x%x\n", toInt(r_ecx)); System.out.printf(">>> EDX = 0x%x\n", toInt(r_edx)); u.close(); } static void test_x86_64() { long rax = 0x71f3029efd49d41dL; long rbx = 0xd87b45277f133ddbL; long rcx = 0xab40d1ffd8afc461L; long rdx = 0x919317b4a733f01L; long rsi = 0x4c24e753a17ea358L; long rdi = 0xe509a57d2571ce96L; long r8 = 0xea5b108cc2b9ab1fL; long r9 = 0x19ec097c8eb618c1L; long r10 = 0xec45774f00c5f682L; long r11 = 0xe17e9dbec8c074aaL; long r12 = 0x80f86a8dc0f6d457L; long r13 = 0x48288ca5671c5492L; long r14 = 0x595f72f6e4017f6eL; long r15 = 0x1efd97aea331ccccL; long rsp = ADDRESS + 0x200000; System.out.print("Emulate x86_64 code\n"); // Initialize emulator in X86-64bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_64); // map 2MB memory for this emulation u.mem_map(ADDRESS, 2 * 1024 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(ADDRESS, X86_CODE64); // initialize machine registers u.reg_write(Unicorn.UC_X86_REG_RSP, toBytes(rsp)); u.reg_write(Unicorn.UC_X86_REG_RAX, toBytes(rax)); u.reg_write(Unicorn.UC_X86_REG_RBX, toBytes(rbx)); u.reg_write(Unicorn.UC_X86_REG_RCX, toBytes(rcx)); u.reg_write(Unicorn.UC_X86_REG_RDX, toBytes(rdx)); u.reg_write(Unicorn.UC_X86_REG_RSI, toBytes(rsi)); u.reg_write(Unicorn.UC_X86_REG_RDI, toBytes(rdi)); u.reg_write(Unicorn.UC_X86_REG_R8, toBytes(r8)); u.reg_write(Unicorn.UC_X86_REG_R9, toBytes(r9)); u.reg_write(Unicorn.UC_X86_REG_R10, toBytes(r10)); u.reg_write(Unicorn.UC_X86_REG_R11, toBytes(r11)); u.reg_write(Unicorn.UC_X86_REG_R12, toBytes(r12)); u.reg_write(Unicorn.UC_X86_REG_R13, toBytes(r13)); u.reg_write(Unicorn.UC_X86_REG_R14, toBytes(r14)); u.reg_write(Unicorn.UC_X86_REG_R15, toBytes(r15)); // tracing all basic blocks with customized callback u.hook_add(new MyBlockHook(), 1, 0, null); // tracing all instructions in the range [ADDRESS, ADDRESS+20] u.hook_add(new MyCode64Hook(), ADDRESS, ADDRESS+20, null); // tracing all memory WRITE access (with @begin > @end) u.hook_add(new MyWrite64Hook(), 1, 0, null); // tracing all memory READ access (with @begin > @end) u.hook_add(new MyRead64Hook(), 1, 0, null); // emulate machine code in infinite time (last param = 0), or when // finishing all the code. u.emu_start(ADDRESS, ADDRESS + X86_CODE64.length, 0, 0); // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); byte[] r_rax = u.reg_read(Unicorn.UC_X86_REG_RAX, 8); byte[] r_rbx = u.reg_read(Unicorn.UC_X86_REG_RBX, 8); byte[] r_rcx = u.reg_read(Unicorn.UC_X86_REG_RCX, 8); byte[] r_rdx = u.reg_read(Unicorn.UC_X86_REG_RDX, 8); byte[] r_rsi = u.reg_read(Unicorn.UC_X86_REG_RSI, 8); byte[] r_rdi = u.reg_read(Unicorn.UC_X86_REG_RDI, 8); byte[] r_r8 = u.reg_read(Unicorn.UC_X86_REG_R8, 8); byte[] r_r9 = u.reg_read(Unicorn.UC_X86_REG_R9, 8); byte[] r_r10 = u.reg_read(Unicorn.UC_X86_REG_R10, 8); byte[] r_r11 = u.reg_read(Unicorn.UC_X86_REG_R11, 8); byte[] r_r12 = u.reg_read(Unicorn.UC_X86_REG_R12, 8); byte[] r_r13 = u.reg_read(Unicorn.UC_X86_REG_R13, 8); byte[] r_r14 = u.reg_read(Unicorn.UC_X86_REG_R14, 8); byte[] r_r15 = u.reg_read(Unicorn.UC_X86_REG_R15, 8); System.out.printf(">>> RAX = 0x%x\n", toInt(r_rax)); System.out.printf(">>> RBX = 0x%x\n", toInt(r_rbx)); System.out.printf(">>> RCX = 0x%x\n", toInt(r_rcx)); System.out.printf(">>> RDX = 0x%x\n", toInt(r_rdx)); System.out.printf(">>> RSI = 0x%x\n", toInt(r_rsi)); System.out.printf(">>> RDI = 0x%x\n", toInt(r_rdi)); System.out.printf(">>> R8 = 0x%x\n", toInt(r_r8)); System.out.printf(">>> R9 = 0x%x\n", toInt(r_r9)); System.out.printf(">>> R10 = 0x%x\n", toInt(r_r10)); System.out.printf(">>> R11 = 0x%x\n", toInt(r_r11)); System.out.printf(">>> R12 = 0x%x\n", toInt(r_r12)); System.out.printf(">>> R13 = 0x%x\n", toInt(r_r13)); System.out.printf(">>> R14 = 0x%x\n", toInt(r_r14)); System.out.printf(">>> R15 = 0x%x\n", toInt(r_r15)); u.close(); } static void test_x86_16() { byte[] eax = toBytes(7); byte[] ebx = toBytes(5); byte[] esi = toBytes(6); System.out.print("Emulate x86 16-bit code\n"); // Initialize emulator in X86-16bit mode Unicorn u = new Unicorn(Unicorn.UC_ARCH_X86, Unicorn.UC_MODE_16); // map 8KB memory for this emulation u.mem_map(0, 8 * 1024, Unicorn.UC_PROT_ALL); // write machine code to be emulated to memory u.mem_write(0, X86_CODE16); // initialize machine registers u.reg_write(Unicorn.UC_X86_REG_EAX, eax); u.reg_write(Unicorn.UC_X86_REG_EBX, ebx); u.reg_write(Unicorn.UC_X86_REG_ESI, esi); // emulate machine code in infinite time (last param = 0), or when // finishing all the code. u.emu_start(0, X86_CODE16.length, 0, 0); // now print out some registers System.out.print(">>> Emulation done. Below is the CPU context\n"); // read from memory byte[] tmp = u.mem_read(11, 1); System.out.printf(">>> Read 1 bytes from [0x%x] = 0x%x\n", 11, toInt(tmp)); u.close(); } public static void main(String args[]) { if (args.length == 1) { if (args[0].equals("-32")) { test_i386(); test_i386_inout(); test_i386_jump(); test_i386_loop(); test_i386_invalid_mem_read(); test_i386_invalid_mem_write(); test_i386_jump_invalid(); } if (args[0].equals("-64")) { test_x86_64(); } if (args[0].equals("-16")) { test_x86_16(); } // test memleak if (args[0].equals("-0")) { while(true) { test_i386(); // test_x86_64(); } } } else { System.out.print("Syntax: java Sample_x86 <-16|-32|-64>\n"); } } }