| name | rev-idapython |
| description | IDAPython and IDALib script reference for reverse engineering. Activate when the user needs to write IDAPython scripts in IDA, use IDALib for headless analysis, operate on IDB databases, debug with IDA, manipulate memory/registers, traverse functions/blocks/instructions, work with Hex-Rays decompiler API, handle obfuscation, or batch-process binaries. |
rev-idapython - IDAPython / IDALib Script Reference
IDAPython script snippets for IDA interactive use and IDALib headless analysis. Use as reference when generating IDAPython code.
- IDAPython: scripts run inside IDA GUI (Script Command, plugin, or IDC console)
- IDALib: headless mode introduced in IDA 9.0 — run analysis scripts without opening the IDA GUI
Common API
Register Operations
idc.get_reg_value('rax')
idaapi.set_reg_val("rax", 1234)
Debug Memory Operations
idc.read_dbg_byte(addr)
idc.read_dbg_memory(addr, size)
idc.read_dbg_dword(addr)
idc.read_dbg_qword(addr)
idc.patch_dbg_byte(addr, val)
idc.add_bpt(0x409437) # add breakpoint
idaapi.get_imagebase() # get image base address
Local Memory Operations (modifies IDB database)
idc.get_qword(addr)
idc.patch_qword(addr, val)
idc.patch_dword(addr, val)
idc.patch_word(addr, val)
idc.patch_byte(addr, val)
idc.get_db_byte(addr)
idc.get_bytes(addr, size)
idaapi.get_dword(addr)
idc.get_strlit_contents # read string literal
Disassembly
GetDisasm(addr) # get disassembly text
idc.next_head(ea) # get next instruction address
idc.create_insn(addr) # c, Make Code
ida_bytes.create_strlit # create string, same as 'A' key
ida_funcs.add_func(addr) # p, create function
idc.del_items(addr) # U, undefine
Address Conversion
idc.get_name_ea(0, '_sub_6051') # get address by function name
Function Operations
ida_funcs.get_func(ea) # get function descriptor
# enumerate all functions
for func in idautils.Functions():
print("0x%x, %s" % (func, idc.get_func_name(func)))
Code Snippets
Byte Pattern Search
import ida_bytes
import ida_idaapi
import ida_funcs
import idc
# find_bytes_list("90 90 90 90 90")
# find_bytes_list("55 ??")
# returns list of matching addresses
def find_bytes_list(bytes_pattern):
ea = -1
result = []
while True:
ea = idc.find_bytes(bytes_pattern, ea + 1)
if ea == ida_idaapi.BADADDR:
break
result.append(ea)
return result
Appcall - Call Debuggee Functions
# test check_passwd(char *passwd) -> int
passwd = ida_idd.Appcall.byref("MyFirstGuess")
res = ida_idd.Appcall.check_passwd(passwd)
if res.value == 0:
print("Good passwd !")
else:
print("Bad passwd...")
# Explicitly create the buffer as a byref object
s_in = Appcall.byref("SomeEncryptedBuffer")
# Buffers are always returned byref
s_out = Appcall.buffer(" ", SizeOfBuffer)
# Call the debuggee
Appcall.decrypt_buffer(s_in, s_out, SizeOfBuffer)
# Print the result
print "decrypted=", s_out.value
loadlib = Appcall.proto("kernel32_LoadLibraryA", "int __stdcall loadlib(const char *fn);")
hmod = loadlib("dll_to_inject.dll")
getlasterror = Appcall.proto("kernel32_GetLastError", "DWORD __stdcall GetLastError();")
print "lasterror=", getlasterror()
getcmdline = Appcall.proto("kernel32_GetCommandLineA", "const char *__stdcall getcmdline();")
print "command line:", getcmdline()
Cross References
for ref in idautils.XrefsTo(ea):
print(hex(ref.frm))
# shorthand
[ref.frm for ref in idautils.XrefsTo(start_ea)]
Basic Block Traversal
fn = 0x4800
f_blocks = idaapi.FlowChart(idaapi.get_func(fn), flags=idaapi.FC_PREDS)
for block in f_blocks:
print(hex(block.start_ea))
# successor blocks
for succ in block.succs():
print hex(succ.start_ea)
# predecessor blocks
for pred in block.preds():
print hex(pred.start_ea)
Debug Memory Read/Write
def patch_dbg_mem(addr, data):
for i in range(len(data)):
idc.patch_dbg_byte(addr + i, data[i])
def read_dbg_mem(addr, size):
dd = []
for i in range(size):
dd.append(idc.read_dbg_byte(addr + i))
return bytes(dd)
Read std::string (64-bit)
def dbg_read_cppstr_64(objectAddr):
strPtr = idc.read_dbg_qword(objectAddr)
result = ''
i = 0
while True:
onebyte = idc.read_dbg_byte(strPtr + i)
if onebyte == 0:
break
else:
result += chr(onebyte)
i += 1
return result
Read C String (64-bit)
def dbg_read_cstr_64(objectAddr):
strPtr = objectAddr
result = ''
i = 0
while True:
onebyte = idc.read_dbg_byte(strPtr + i)
if onebyte == 0:
break
else:
result += chr(onebyte)
i += 1
return result
Parse GNU C++ std::map
import idautils
import idaapi
import idc
def parse_gnu_map_header(address):
root = idc.read_dbg_qword(address + 0x10)
return root
def parse_gnu_map_node(address):
left = idc.read_dbg_qword(address + 0x10)
right = idc.read_dbg_qword(address + 0x18)
data = address + 0x20
return left, right, data
def parse_gnu_map_travel(address):
# address <- std::map struct address
result = []
worklist = [parse_gnu_map_header(address)]
while len(worklist) > 0:
addr = worklist.pop()
(left, right, data) = parse_gnu_map_node(addr)
if left > 0: worklist.append(left)
if right > 0: worklist.append(right);
result.append(data)
return result
# example
elements = parse_gnu_map_travel(0x0000557518073EB0)
for elem in elements:
print(hex(elem))
Read XMM Register (Debug)
def read_xmm_reg(name):
rv = idaapi.regval_t()
idaapi.get_reg_val(name, rv)
return (struct.unpack('Q', rv.bytes())[0])
Step Over and Wait for Debug Event
while ida_dbg.step_over():
wait_for_next_event(WFNE_ANY, -1)
rip = idc.get_reg_value("rip")
# .....
Iterate Instructions in a Function
for ins in idautils.FuncItems(0x401000):
print(hex(ins))
Get Function Callees (Instruction-Based)
def ida_get_callees(func_addr: int) -> list:
callees = []
for head in idautils.Heads(func_addr, idaapi.get_func(func_addr).end_ea):
if idaapi.is_call_insn(head):
callee_ea = idc.get_operand_value(head, 0)
callees.append(callee_ea)
return callees
Double / Complex Number Memory Operations
def float_to_double_bytearray(value):
double_value = ctypes.c_double(value)
byte_array = bytearray(ctypes.string_at(ctypes.byref(double_value), ctypes.sizeof(double_value)))
return byte_array
def set_pos(x, y): # complex<double, double>
rbp = idc.get_reg_value("rbp")
complex_base = rbp - 0x260
patch_dbg_mem(complex_base, float_to_double_bytearray(x))
patch_dbg_mem(complex_base + 8, float_to_double_bytearray(y))
set_pos(5.0, 6.0)
Import Table
Enumerate Import Table
import ida_nalt
nimps = ida_nalt.get_import_module_qty()
print("Found %d import(s)..." % nimps)
for i in range(nimps):
name = ida_nalt.get_import_module_name(i)
if not name:
print("Failed to get import module name for #%d" % i)
name = "<unnamed>"
print("Walking imports for module %s" % name)
def imp_cb(ea, name, ordinal):
if not name:
print("%08x: ordinal #%d" % (ea, ordinal))
else:
print("%08x: %s (ordinal #%d)" % (ea, name, ordinal))
return True
ida_nalt.enum_import_names(i, imp_cb)
print("All done...")
Check if Address is an Import Function
def ida_is_import_function(addr: int) -> bool:
is_find = False
nimps = ida_nalt.get_import_module_qty()
for i in range(nimps):
def imp_cb(ea, name, ordinal):
nonlocal is_find
if ea == addr:
is_find = True
return False
return True
ida_nalt.enum_import_names(i, imp_cb)
return is_find
Enumerate Import Addresses
def ida_enum_import_addr() -> List[int]:
import_addrs = []
nimps = ida_nalt.get_import_module_qty()
for i in range(nimps):
def imp_cb(ea, name, ordinal):
nonlocal import_addrs
import_addrs.append(ea)
return True
ida_nalt.enum_import_names(i, imp_cb)
return import_addrs
Type Information
Struct Member Traversal
def extract_struct_members(type_name):
fields = []
tif = ida_typeinf.tinfo_t()
if tif.get_named_type(None, type_name):
offset = 0
for iter in tif.iter_struct(): # udm
fsize = iter.type.get_size()
fields.append({
"offset": iter.offset // 8, # bit offset
"size": fsize,
"type": iter.type._print()
})
offset += fsize
else:
print(f"Unable to get {type_name} type info.")
return fields
extract_struct_members("sqlite3_vfs")
Enumerate All Types
til = ida_typeinf.get_idati()
for type_name in til.get_type_names():
print(type_name)
List All Struct Types
def list_struct_types():
types = []
til = ida_typeinf.get_idati()
for type_name in til.get_type_names():
tif = ida_typeinf.tinfo_t()
if tif.get_named_type(None, type_name):
if tif.is_struct():
types.append(type_name)
return types
Hex-Rays Decompiler API
Decompile a Function
# verified: IDA 9.0
dec = ida_hexrays.decompile(func_addr)
# dec is an object, str(dec) converts to text
print(str(dec))
Print Microcode at Different Maturity Levels
def print_microcode(func_ea):
maturity = ida_hexrays.MMAT_GLBOPT3
# maturity:
# MMAT_ZERO, ///< microcode does not exist
# MMAT_GENERATED, ///< generated microcode
# MMAT_PREOPTIMIZED, ///< preoptimized pass is complete
# MMAT_LOCOPT, ///< local optimization of each basic block is complete.
# ///< control flow graph is ready too.
# MMAT_CALLS, ///< detected call arguments
# MMAT_GLBOPT1, ///< performed the first pass of global optimization
# MMAT_GLBOPT2, ///< most global optimization passes are done
# MMAT_GLBOPT3, ///< completed all global optimization. microcode is fixed now.
# MMAT_LVARS, ///< allocated local variables
hf = ida_hexrays.hexrays_failure_t()
pfn = idaapi.get_func(func_ea)
rng = ida_hexrays.mba_ranges_t(pfn)
mba = ida_hexrays.gen_microcode(rng, hf, None,
ida_hexrays.DECOMP_WARNINGS, maturity)
vp = ida_hexrays.vd_printer_t()
mba._print(vp)
print_microcode(0x1229)
Custom Instruction to User-Defined Call
class udc_exit_t(ida_hexrays.udc_filter_t):
def __init__(self, code, name):
ida_hexrays.udc_filter_t.__init__(self)
if not self.init("int __usercall %s@<R0>(int status@<R1>);" % name):
raise Exception("Couldn't initialize udc_exit_t instance")
self.code = code
self.installed = False
def match(self, cdg):
return cdg.insn.itype == ida_allins.ARM_svc and cdg.insn.Op1.value == self.code
def install(self):
ida_hexrays.install_microcode_filter(self, True);
self.installed = True
def uninstall(self):
ida_hexrays.install_microcode_filter(self, False);
self.installed = False
def toggle_install(self):
if self.installed:
self.uninstall()
else:
self.install()
udc_exit = udc_exit_t(0x900001, "svc_exit")
udc_exit.toggle_install()
Hexrays_Hooks
class MicrocodeCallback(ida_hexrays.Hexrays_Hooks):
def __init__(self, *args):
super().__init__(*args)
def microcode(self, mba: ida_hexrays.mba_t) -> "int":
print("microcode generated.")
return 0
r = MicrocodeCallback()
r.hook()
Obfuscation Helpers
OLLVM - Set Breakpoints on Real Blocks
Set breakpoints on all real block entry addresses. Real blocks are identified by finding predecessors of the OLLVM dispatcher merge point.
Note: identifying real blocks by xrefs to the merge point is a heuristic and may not be fully accurate. Use IDA breakpoint groups for batch management.
fn = 0x401F60
ollvm_tail = 0x405D4B # OLLVM real block merge point
f_blocks = idaapi.FlowChart(idaapi.get_func(fn), flags=idaapi.FC_PREDS)
for block in f_blocks:
for succ in block.succs():
if succ.start_ea == ollvm_tail:
print(hex(block.start_ea))
idc.add_bpt(block.start_ea)
Batch Add Breakpoints
def brkall(l):
for addr in l:
idc.add_bpt(addr)
Firmware Helpers
Search x86 Function Prologues and Create Functions
# verified: IDA 9.0
def make_x86_func():
func_headers = find_bytes_list("55 8B")
for h in func_headers:
idc.del_items(h)
idc.create_insn(h)
ida_funcs.add_func(h)
Basic Block Utilities
Get Basic Block Size
# verified: IDA 9.0
def get_bb_size(bbaddr):
fn = bbaddr
f_blocks = idaapi.FlowChart(idaapi.get_func(fn), flags=idaapi.FC_PREDS)
for block in f_blocks:
if block.start_ea == bbaddr:
return block.end_ea - block.start_ea
raise Exception("Not found")
Get Basic Block by Address
def ida_get_bb(ea):
f_blocks = idaapi.FlowChart(idaapi.get_func(ea), flags=idaapi.FC_PREDS)
for block in f_blocks:
if block.start_ea <= ea and ea < block.end_ea:
return block
return None
Instruction Utilities
Search Next Instruction by Keyword
# verified: IDA 9.0
def search_next_insn(addr, insnkey, max_search=0x100):
cnt = 0
while cnt < max_search:
addr = idc.next_head(addr)
dis = GetDisasm(addr)
if insnkey in dis:
return addr
cnt += 1
return None
# example
# search_next_insn(addr, 'movdqa')
Undefine a Range (U key equivalent)
# verified: IDA 9.0
def undefine_range(start, end):
for i in range(start, end):
idc.del_items(i)
# example
# undefine_range(func_start, func_end)
Search Disassembly Text
# verified: IDA 9.0
def search_text_all(text):
import idaapi, idc
start_ea = 0
result = []
while True:
start_ea = idaapi.find_text(ustr=text, x=0, y=0,
sflag=idaapi.SEARCH_DOWN, start_ea=start_ea)
if start_ea == idc.BADADDR:
break
result.append(start_ea)
start_ea = idc.next_head(start_ea)
return result
# example
for x in search_text_all('movdqa'):
print(GetDisasm(x))
NOP Function
import idaapi
import idautils
import idc
def nop_func(addr_func, arch='arm'):
func = ida_funcs.get_func(addr_func)
if not func:
print("Function not found!")
return
start = func.start_ea
end = func.end_ea
print(f"Nopping function at: 0x{start:x} - 0x{end:x}")
if arch == 'x86':
nop_bytes = [0x90] # x86 NOP
elif arch == 'arm':
nop_bytes = [0x1F, 0x20, 0x03, 0xD5] # ARM NOP
else:
print(f"Unsupported architecture: {arch}")
return
ea = start
while ea < end:
insn = ida_ua.insn_t()
length = ida_ua.decode_insn(insn, ea)
if length == 0:
print(f"Failed to decode instruction at: 0x{ea:x}")
break
nop_len = len(nop_bytes)
for i in range(0, length, nop_len):
for j in range(nop_len):
if i + j < length:
idc.patch_byte(ea + i + j, nop_bytes[j])
ea += length
print("Nopping complete.")
# example
nop_func(0x401000, 'arm')
IDALib (Headless IDA, IDA 9.0+)
IDALib allows running IDAPython analysis scripts without opening the IDA GUI.
Installation
cd idalib/python
pip install .
python py-activate-idalib.py
Basic Usage
import idapro # must be the first import
import idautils
import idc
# open idb/binary file
ida.open_database("samples/patch.so", True)
# enumerate functions
for func in idautils.Functions():
func_name = idc.get_func_name(func)
print("Function Name: {}, Address: {}".format(func_name, hex(func)))
# close and save idb
ida.close_database(save=True)
Batch Decompile to JSON
Usage: decompile.py <input_file_elf> <output_file_json>
decompile.py:
import idapro
import ida_hexrays
import idautils
import idc
import os
import sys
import json
def _decompile_internal():
result = []
for func in idautils.Functions():
func_name = idc.get_func_name(func)
print("Function Name: {}, Address: {}".format(func_name, hex(func)))
dec_obj = ida_hexrays.decompile(func)
if dec_obj is None:
continue
dec_str = str(dec_obj)
result.append({
'name': func_name,
'address': hex(func),
'decompiled': dec_str
})
return result
def decomple_export(file, out_file):
ida.open_database(file, True)
r = _decompile_internal()
ida.close_database(save=False)
open(out_file, "w").write(json.dumps(r, indent=4))
if __name__ == "__main__":
if len(sys.argv) != 3:
print("Usage: {} <input_file_elf> <output_file_json>".format(sys.argv[0]))
sys.exit(1)
decomple_export(sys.argv[1], sys.argv[2])
Multiprocess Batch Decompile
import os
import time
from multiprocessing import Pool
args = {
"NUM_WORKERS": 8,
"INPUT_DIR": "/Users/ctf/idek2024/baby2/baby",
"OUTPUT_DIR": "/Users/ctf/idek2024/baby2/decompiled",
"NUM_MAX_RETRY": 3
}
def decomple_one(file, out_file):
retry = 0
while True:
os.system("python3 decompile.py {} {}".format(file, out_file))
if os.path.exists(out_file):
break
retry += 1
if retry >= args["NUM_MAX_RETRY"]:
return "Failed to decompile {}".format(file)
time.sleep(1)
return None
if __name__ == "__main__":
if not os.path.exists(args["OUTPUT_DIR"]):
os.makedirs(args["OUTPUT_DIR"])
files = os.listdir(args["INPUT_DIR"])
files = [os.path.join(args["INPUT_DIR"], f) for f in files]
out_files = [os.path.join(args["OUTPUT_DIR"], os.path.basename(f) + ".json" ) for f in files]
with Pool(args["NUM_WORKERS"]) as p:
r = p.starmap(decomple_one, zip(files, out_files))
for i in r:
if i is not None:
print(i)