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pydbg.py
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pydbg.py
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#!c:\python\python.exe
#
# PyDBG
# Copyright (C) 2006 Pedram Amini <[email protected]>
#
# $Id: pydbg.py 253 2011-01-24 19:13:57Z my.name.is.sober $
#
# This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public
# License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later
# version.
#
# 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
#
'''
@author: Pedram Amini
@license: GNU General Public License 2.0 or later
@contact: [email protected]
@organization: www.openrce.org
'''
import os.path
import sys
import copy
import signal
import struct
import pydasm
import socket
from my_ctypes import *
from defines import *
from windows_h import *
# macos compatability.
try:
kernel32 = windll.kernel32
advapi32 = windll.advapi32
ntdll = windll.ntdll
iphlpapi = windll.iphlpapi
except:
kernel32 = CDLL(os.path.join(os.path.dirname(__file__), "libmacdll.dylib"))
advapi32 = kernel32
from breakpoint import *
from hardware_breakpoint import *
from memory_breakpoint import *
from memory_snapshot_block import *
from memory_snapshot_context import *
from pdx import *
from system_dll import *
class pydbg:
'''
This class implements standard low leven functionality including:
- The load() / attach() routines.
- The main debug event loop.
- Convenience wrappers for commonly used Windows API.
- Single step toggling routine.
- Win32 error handler wrapped around PDX.
- Base exception / event handler routines which are meant to be overridden.
Higher level functionality is also implemented including:
- Register manipulation.
- Soft (INT 3) breakpoints.
- Memory breakpoints (page permissions).
- Hardware breakpoints.
- Exception / event handling call backs.
- Pydasm (libdasm) disassembly wrapper.
- Process memory snapshotting and restoring.
- Endian manipulation routines.
- Debugger hiding.
- Function resolution.
- "Intelligent" memory derefencing.
- Stack/SEH unwinding.
- Etc...
'''
STRING_EXPLORATON_BUF_SIZE = 256
STRING_EXPLORATION_MIN_LENGTH = 2
####################################################################################################################
def __init__ (self, ff=True, cs=False):
'''
Set the default attributes. See the source if you want to modify the default creation values.
@type ff: Boolean
@param ff: (Optional, Def=True) Flag controlling whether or not pydbg attaches to forked processes
@type cs: Boolean
@param cs: (Optional, Def=False) Flag controlling whether or not pydbg is in client/server (socket) mode
'''
# private variables, internal use only:
self._restore_breakpoint = None # breakpoint to restore
self._guarded_pages = set() # specific pages we set PAGE_GUARD on
self._guards_active = True # flag specifying whether or not guard pages are active
self.page_size = 0 # memory page size (dynamically resolved at run-time)
self.pid = 0 # debuggee's process id
self.h_process = None # debuggee's process handle
self.h_thread = None # handle to current debuggee thread
self.debugger_active = True # flag controlling the main debugger event handling loop
self.follow_forks = ff # flag controlling whether or not pydbg attaches to forked processes
self.client_server = cs # flag controlling whether or not pydbg is in client/server mode
self.callbacks = {} # exception callback handler dictionary
self.system_dlls = [] # list of loaded system dlls
self.dirty = False # flag specifying that the memory space of the debuggee was modified
self.system_break = None # the address at which initial and forced breakpoints occur at
self.peb = None # process environment block address
self.tebs = {} # dictionary of thread IDs to thread environment block addresses
# internal variables specific to the last triggered exception.
self.context = None # thread context of offending thread
self.dbg = None # DEBUG_EVENT
self.exception_address = None # from dbg.u.Exception.ExceptionRecord.ExceptionAddress
self.write_violation = None # from dbg.u.Exception.ExceptionRecord.ExceptionInformation[0]
self.violation_address = None # from dbg.u.Exception.ExceptionRecord.ExceptionInformation[1]
self.exception_code = None # from dbg.u.Exception.ExceptionRecord.ExceptionCode
self.breakpoints = {} # internal breakpoint dictionary, keyed by address
self.memory_breakpoints = {} # internal memory breakpoint dictionary, keyed by base address
self.hardware_breakpoints = {} # internal hardware breakpoint array, indexed by slot (0-3 inclusive)
self.memory_snapshot_blocks = [] # list of memory blocks at time of memory snapshot
self.memory_snapshot_contexts = [] # list of threads contexts at time of memory snapshot
self.first_breakpoint = True # this flag gets disabled once the windows initial break is handled
self.memory_breakpoint_hit = 0 # address of hit memory breakpoint or zero on miss
# designates whether or not the violation was in reaction to a memory
# breakpoint hit or other unrelated event.
self.hardware_breakpoint_hit = None # hardware breakpoint on hit or None on miss
# designates whether or not the single step event was in reaction to
# a hardware breakpoint hit or other unrelated event.
self.instruction = None # pydasm instruction object, propagated by self.disasm()
self.mnemonic = None # pydasm decoded instruction mnemonic, propagated by self.disasm()
self.op1 = None # pydasm decoded 1st operand, propagated by self.disasm()
self.op2 = None # pydasm decoded 2nd operand, propagated by self.disasm()
self.op3 = None # pydasm decoded 3rd operand, propagated by self.disasm()
# control debug/error logging.
self._log = lambda msg: None #sys.stderr.write("PDBG_LOG> " + msg + "\n")
self._err = lambda msg: sys.stderr.write("PDBG_ERR> " + msg + "\n")
# determine the system page size.
system_info = SYSTEM_INFO()
kernel32.GetSystemInfo(byref(system_info))
self.page_size = system_info.dwPageSize
# determine the system DbgBreakPoint address. this is the address at which initial and forced breaks happen.
# XXX - need to look into fixing this for pydbg client/server.
self.system_break = self.func_resolve("ntdll.dll", "DbgBreakPoint")
self._log("system page size is %d" % self.page_size)
####################################################################################################################
def addr_to_dll (self, address):
'''
Return the system DLL that contains the address specified.
@type address: DWORD
@param address: Address to search system DLL ranges for
@rtype: system_dll
@return: System DLL that contains the address specified or None if not found.
'''
for dll in self.system_dlls:
if dll.base < address < dll.base + dll.size:
return dll
return None
####################################################################################################################
def addr_to_module (self, address):
'''
Return the MODULEENTRY32 structure for the module that contains the address specified.
@type address: DWORD
@param address: Address to search loaded module ranges for
@rtype: MODULEENTRY32
@return: MODULEENTRY32 strucutre that contains the address specified or None if not found.
'''
found = None
for module in self.iterate_modules():
if module.modBaseAddr < address < module.modBaseAddr + module.modBaseSize:
# we have to make a copy of the 'module' since it is an iterator and will be blown away.
# the reason we can't "break" out of the loop is because there will be a handle leak.
# and we can't use enumerate_modules() because we need the entire module structure.
# so there...
found = copy.copy(module)
return found
####################################################################################################################
def attach (self, pid):
'''
Attach to the specified process by PID. Saves a process handle in self.h_process and prevents debuggee from
exiting on debugger quit.
@type pid: Integer
@param pid: Process ID to attach to
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
self._log("attaching to pid %d" % pid)
# obtain necessary debug privileges.
self.get_debug_privileges()
self.pid = pid
self.open_process(pid)
self.debug_active_process(pid)
# allow detaching on systems that support it.
try:
self.debug_set_process_kill_on_exit(False)
except:
pass
# enumerate the TEBs and add them to the internal dictionary.
for thread_id in self.enumerate_threads():
thread_handle = self.open_thread(thread_id)
thread_context = self.get_thread_context(thread_handle)
selector_entry = LDT_ENTRY()
if not kernel32.GetThreadSelectorEntry(thread_handle, thread_context.SegFs, byref(selector_entry)):
self.win32_error("GetThreadSelectorEntry()")
self.close_handle(thread_handle)
teb = selector_entry.BaseLow
teb += (selector_entry.HighWord.Bits.BaseMid << 16) + (selector_entry.HighWord.Bits.BaseHi << 24)
# add this TEB to the internal dictionary.
self.tebs[thread_id] = teb
# if the PEB has not been set yet, do so now.
if not self.peb:
self.peb = self.read_process_memory(teb + 0x30, 4)
self.peb = struct.unpack("<L", self.peb)[0]
return self.ret_self()
####################################################################################################################
def bp_del (self, address):
'''
Removes the breakpoint from target address.
@see: bp_set(), bp_del_all(), bp_is_ours()
@type address: DWORD or List
@param address: Address or list of addresses to remove breakpoint from
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
# if a list of addresses to remove breakpoints from was supplied.
if type(address) is list:
# pass each lone address to ourself.
for addr in address:
self.bp_del(addr)
return self.ret_self()
self._log("bp_del(0x%08x)" % address)
# ensure a breakpoint exists at the target address.
if self.breakpoints.has_key(address):
# restore the original byte.
self.write_process_memory(address, self.breakpoints[address].original_byte)
self.set_attr("dirty", True)
# remove the breakpoint from the internal list.
del self.breakpoints[address]
return self.ret_self()
####################################################################################################################
def bp_del_all (self):
'''
Removes all breakpoints from the debuggee.
@see: bp_set(), bp_del(), bp_is_ours()
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
self._log("bp_del_all()")
for bp in self.breakpoints.keys():
self.bp_del(bp)
return self.ret_self()
####################################################################################################################
def bp_del_hw (self, address=None, slot=None):
'''
Removes the hardware breakpoint from the specified address or slot. Either an address or a slot must be
specified, but not both.
@see: bp_set_hw(), bp_del_hw_all()
@type address: DWORD
@param address: (Optional) Address to remove hardware breakpoint from.
@type slot: Integer (0 through 3)
@param slot: (Optional)
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
if address == slot == None:
raise pdx("hw bp address or slot # must be specified.")
if not address and slot not in xrange(4):
raise pdx("invalid hw bp slot: %d. valid range is 0 through 3" % slot)
# de-activate the hardware breakpoint for all active threads.
for thread_id in self.enumerate_threads():
context = self.get_thread_context(thread_id=thread_id)
if address:
if context.Dr0 == address: slot = 0
elif context.Dr1 == address: slot = 1
elif context.Dr2 == address: slot = 2
elif context.Dr3 == address: slot = 3
# mark slot as inactive.
# bits 0, 2, 4, 6 for local (L0 - L3)
# bits 1, 3, 5, 7 for global (L0 - L3)
context.Dr7 &= ~(1 << (slot * 2))
# remove address from the specified slot.
if slot == 0: context.Dr0 = 0x00000000
elif slot == 1: context.Dr1 = 0x00000000
elif slot == 2: context.Dr2 = 0x00000000
elif slot == 3: context.Dr3 = 0x00000000
# remove the condition (RW0 - RW3) field from the appropriate slot (bits 16/17, 20/21, 24,25, 28/29)
context.Dr7 &= ~(3 << ((slot * 4) + 16))
# remove the length (LEN0-LEN3) field from the appropriate slot (bits 18/19, 22/23, 26/27, 30/31)
context.Dr7 &= ~(3 << ((slot * 4) + 18))
# set the thread context.
self.set_thread_context(context, thread_id=thread_id)
# remove the breakpoint from the internal list.
del self.hardware_breakpoints[slot]
return self.ret_self()
####################################################################################################################
def bp_del_hw_all (self):
'''
Removes all hardware breakpoints from the debuggee.
@see: bp_set_hw(), bp_del_hw()
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
if self.hardware_breakpoints.has_key(0): self.bp_del_hw(slot=0)
if self.hardware_breakpoints.has_key(1): self.bp_del_hw(slot=1)
if self.hardware_breakpoints.has_key(2): self.bp_del_hw(slot=2)
if self.hardware_breakpoints.has_key(3): self.bp_del_hw(slot=3)
return self.ret_self()
####################################################################################################################
def bp_del_mem (self, address):
'''
Removes the memory breakpoint from target address.
@see: bp_del_mem_all(), bp_set_mem(), bp_is_ours_mem()
@type address: DWORD
@param address: Address or list of addresses to remove memory breakpoint from
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
self._log("bp_del_mem(0x%08x)" % address)
# ensure a memory breakpoint exists at the target address.
if self.memory_breakpoints.has_key(address):
size = self.memory_breakpoints[address].size
mbi = self.memory_breakpoints[address].mbi
# remove the memory breakpoint from our internal list.
del self.memory_breakpoints[address]
# page-aligned target memory range.
start = mbi.BaseAddress
end = address + size # non page-aligned range end
end = end + self.page_size - (end % self.page_size) # page-aligned range end
# for each page in the target range, restore the original page permissions if no other breakpoint exists.
for page in range(start, end, self.page_size):
other_bp_found = False
for mem_bp in self.memory_breakpoints.values():
if page <= mem_bp.address < page + self.page_size:
other_bp_found = True
break
if page <= mem_bp.address + size < page + self.page_size:
other_bp_found = True
break
if not other_bp_found:
try:
self.virtual_protect(page, 1, mbi.Protect & ~PAGE_GUARD)
# remove the page from the set of tracked GUARD pages.
self._guarded_pages.remove(mbi.BaseAddress)
except:
pass
return self.ret_self()
####################################################################################################################
def bp_del_mem_all (self):
'''
Removes all memory breakpoints from the debuggee.
@see: bp_del_mem(), bp_set_mem(), bp_is_ours_mem()
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
self._log("bp_del_mem_all()")
for address in self.memory_breakpoints.keys():
self.bp_del_mem(address)
return self.ret_self()
####################################################################################################################
def bp_is_ours (self, address_to_check):
'''
Determine if a breakpoint address belongs to us.
@see: bp_set(), bp_del(), bp_del_all()
@type address_to_check: DWORD
@param address_to_check: Address to check if we have set a breakpoint at
@rtype: Bool
@return: True if breakpoint in question is ours, False otherwise
'''
if self.breakpoints.has_key(address_to_check):
return True
return False
####################################################################################################################
def bp_is_ours_mem (self, address_to_check):
'''
Determines if the specified address falls within the range of one of our memory breakpoints. When handling
potential memory breakpoint exceptions it is mandatory to check the offending address with this routine as
memory breakpoints are implemented by changing page permissions and the referenced address may very well exist
within the same page as a memory breakpoint but not within the actual range of the buffer we wish to break on.
@see: bp_set_mem(), bp_del_mem(), bp_del_mem_all()
@type address_to_check: DWORD
@param address_to_check: Address to check if we have set a breakpoint on
@rtype: Mixed
@return: The starting address of the buffer our breakpoint triggered on or False if address falls outside range.
'''
for address in self.memory_breakpoints:
size = self.memory_breakpoints[address].size
if address_to_check >= address and address_to_check <= address + size:
return address
return False
####################################################################################################################
def bp_set (self, address, description="", restore=True, handler=None):
'''
Sets a breakpoint at the designated address. Register an EXCEPTION_BREAKPOINT callback handler to catch
breakpoint events. If a list of addresses is submitted to this routine then the entire list of new breakpoints
get the same description and restore. The optional "handler" parameter can be used to identify a function to
specifically handle the specified bp, as opposed to the generic bp callback handler. The prototype of the
callback routines is::
func (pydbg)
return DBG_CONTINUE # or other continue status
@see: bp_is_ours(), bp_del(), bp_del_all()
@type address: DWORD or List
@param address: Address or list of addresses to set breakpoint at
@type description: String
@param description: (Optional) Description to associate with this breakpoint
@type restore: Bool
@param restore: (Optional, def=True) Flag controlling whether or not to restore the breakpoint
@type handler: Function Pointer
@param handler: (Optional, def=None) Optional handler to call for this bp instead of the default handler
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
# if a list of addresses to set breakpoints on from was supplied
if type(address) is list:
# pass each lone address to ourself (each one gets the same description / restore flag).
for addr in address:
self.bp_set(addr, description, restore, handler)
return self.ret_self()
self._log("bp_set(0x%08x)" % address)
# ensure a breakpoint doesn't already exist at the target address.
if not self.breakpoints.has_key(address):
try:
# save the original byte at the requested breakpoint address.
original_byte = self.read_process_memory(address, 1)
# write an int3 into the target process space.
self.write_process_memory(address, "\xCC")
self.set_attr("dirty", True)
# add the breakpoint to the internal list.
self.breakpoints[address] = breakpoint(address, original_byte, description, restore, handler)
except:
raise pdx("Failed setting breakpoint at %08x" % address)
return self.ret_self()
####################################################################################################################
def bp_set_hw (self, address, length, condition, description="", restore=True, handler=None):
'''
Sets a hardware breakpoint at the designated address. Register an EXCEPTION_SINGLE_STEP callback handler to
catch hardware breakpoint events. Setting hardware breakpoints requires the internal h_thread handle be set.
This means that you can not set one outside the context of an debug event handler. If you want to set a hardware
breakpoint as soon as you attach to or load a process, do so in the first chance breakpoint handler.
For more information regarding the Intel x86 debug registers and hardware breakpoints see::
http://pdos.csail.mit.edu/6.828/2005/readings/ia32/IA32-3.pdf
Section 15.2
Alternatively, you can register a custom handler to handle hits on the specific hw breakpoint slot.
*Warning: Setting hardware breakpoints during the first system breakpoint will be removed upon process
continue. A better approach is to set a software breakpoint that when hit will set your hardware breakpoints.
@note: Hardware breakpoints are handled globally throughout the entire process and not a single specific thread.
@see: bp_del_hw(), bp_del_hw_all()
@type address: DWORD
@param address: Address to set hardware breakpoint at
@type length: Integer (1, 2 or 4)
@param length: Size of hardware breakpoint in bytes (byte, word or dword)
@type condition: Integer (HW_ACCESS, HW_WRITE, HW_EXECUTE)
@param condition: Condition to set the hardware breakpoint to activate on
@type description: String
@param description: (Optional) Description of breakpoint
@type restore: Boolean
@param restore: (Optional, def=True) Flag controlling whether or not to restore the breakpoint
@type handler: Function Pointer
@param handler: (Optional, def=None) Optional handler to call for this bp instead of the default handler
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
self._log("bp_set_hw(%08x, %d, %s)" % (address, length, condition))
# instantiate a new hardware breakpoint object for the new bp to create.
hw_bp = hardware_breakpoint(address, length, condition, description, restore, handler=handler)
if length not in (1, 2, 4):
raise pdx("invalid hw breakpoint length: %d." % length)
# length -= 1 because the following codes are used for determining length:
# 00 - 1 byte length
# 01 - 2 byte length
# 10 - undefined
# 11 - 4 byte length
length -= 1
# condition table:
# 00 - break on instruction execution only
# 01 - break on data writes only
# 10 - undefined
# 11 - break on data reads or writes but not instruction fetches
if condition not in (HW_ACCESS, HW_EXECUTE, HW_WRITE):
raise pdx("invalid hw breakpoint condition: %d" % condition)
# check for any available hardware breakpoint slots. there doesn't appear to be any difference between local
# and global as far as we are concerned on windows.
#
# bits 0, 2, 4, 6 for local (L0 - L3)
# bits 1, 3, 5, 7 for global (G0 - G3)
#
# we could programatically search for an open slot in a given thread context with the following code:
#
# available = None
# for slot in xrange(4):
# if context.Dr7 & (1 << (slot * 2)) == 0:
# available = slot
# break
#
# but since we are doing global hardware breakpoints, we rely on ourself for tracking open slots.
if not self.hardware_breakpoints.has_key(0):
available = 0
elif not self.hardware_breakpoints.has_key(1):
available = 1
elif not self.hardware_breakpoints.has_key(2):
available = 2
elif not self.hardware_breakpoints.has_key(3):
available = 3
else:
raise pdx("no hw breakpoint slots available.")
# activate the hardware breakpoint for all active threads.
for thread_id in self.enumerate_threads():
context = self.get_thread_context(thread_id=thread_id)
# mark available debug register as active (L0 - L3).
context.Dr7 |= 1 << (available * 2)
# save our breakpoint address to the available hw bp slot.
if available == 0: context.Dr0 = address
elif available == 1: context.Dr1 = address
elif available == 2: context.Dr2 = address
elif available == 3: context.Dr3 = address
# set the condition (RW0 - RW3) field for the appropriate slot (bits 16/17, 20/21, 24,25, 28/29)
context.Dr7 |= condition << ((available * 4) + 16)
# set the length (LEN0-LEN3) field for the appropriate slot (bits 18/19, 22/23, 26/27, 30/31)
context.Dr7 |= length << ((available * 4) + 18)
# set the thread context.
self.set_thread_context(context, thread_id=thread_id)
# update the internal hardware breakpoint array at the used slot index.
hw_bp.slot = available
self.hardware_breakpoints[available] = hw_bp
return self.ret_self()
####################################################################################################################
def bp_set_mem (self, address, size, description="", handler=None):
'''
Sets a memory breakpoint at the target address. This is implemented by changing the permissions of the page
containing the address to PAGE_GUARD. To catch memory breakpoints you have to register the EXCEPTION_GUARD_PAGE
callback. Within the callback handler check the internal pydbg variable self.memory_breakpoint_hit to
determine if the violation was a result of a direct memory breakpoint hit or some unrelated event.
Alternatively, you can register a custom handler to handle the memory breakpoint. Memory breakpoints are
automatically restored via the internal single step handler. To remove a memory breakpoint, you must explicitly
call bp_del_mem().
@see: bp_is_ours_mem(), bp_del_mem(), bp_del_mem_all()
@type address: DWORD
@param address: Starting address of the buffer to break on
@type size: Integer
@param size: Size of the buffer to break on
@type description: String
@param description: (Optional) Description to associate with this breakpoint
@type handler: Function Pointer
@param handler: (Optional, def=None) Optional handler to call for this bp instead of the default handler
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
self._log("bp_set_mem() buffer range is %08x - %08x" % (address, address + size))
# ensure the target address doesn't already sit in a memory breakpoint range:
if self.bp_is_ours_mem(address):
self._log("a memory breakpoint spanning %08x already exists" % address)
return self.ret_self()
# determine the base address of the page containing the starting point of our buffer.
try:
mbi = self.virtual_query(address)
except:
raise pdx("bp_set_mem(): failed querying address: %08x" % address)
self._log("buffer starting at %08x sits on page starting at %08x" % (address, mbi.BaseAddress))
# individually change the page permissions for each page our buffer spans.
# why do we individually set the page permissions of each page as opposed to a range of pages? because empirical
# testing shows that when you set a PAGE_GUARD on a range of pages, if any of those pages are accessed, then
# the PAGE_GUARD attribute is dropped for the entire range of pages that was originally modified. this is
# undesirable for our purposes when it comes to the ease of restoring hit memory breakpoints.
current_page = mbi.BaseAddress
while current_page <= address + size:
self._log("changing page permissions on %08x" % current_page)
# keep track of explicitly guarded pages, to differentiate from pages guarded by the debuggee / OS.
self._guarded_pages.add(current_page)
self.virtual_protect(current_page, 1, mbi.Protect | PAGE_GUARD)
current_page += self.page_size
# add the breakpoint to the internal list.
self.memory_breakpoints[address] = memory_breakpoint(address, size, mbi, description, handler)
return self.ret_self()
####################################################################################################################
def close_handle (self, handle):
'''
Convenience wraper around kernel32.CloseHandle()
@type handle: Handle
@param handle: Handle to close
@rtype: Bool
@return: Return value from CloseHandle().
'''
return kernel32.CloseHandle(handle)
####################################################################################################################
def dbg_print_all_debug_registers (self):
'''
*** DEBUG ROUTINE ***
This is a debugging routine that was used when debugging hardware breakpoints. It was too useful to be removed
from the release code.
'''
# ensure we have an up to date context for the current thread.
context = self.get_thread_context(self.h_thread)
print "eip = %08x" % context.Eip
print "Dr0 = %08x" % context.Dr0
print "Dr1 = %08x" % context.Dr1
print "Dr2 = %08x" % context.Dr2
print "Dr3 = %08x" % context.Dr3
print "Dr7 = %s" % self.to_binary(context.Dr7)
print " 10987654321098765432109876543210"
print " 332222222222111111111"
####################################################################################################################
def dbg_print_all_guarded_pages (self):
'''
*** DEBUG ROUTINE ***
This is a debugging routine that was used when debugging memory breakpoints. It was too useful to be removed
from the release code.
'''
cursor = 0
# scan through the entire memory range.
while cursor < 0xFFFFFFFF:
try:
mbi = self.virtual_query(cursor)
except:
break
if mbi.Protect & PAGE_GUARD:
address = mbi.BaseAddress
print "PAGE GUARD on %08x" % mbi.BaseAddress
while 1:
address += self.page_size
tmp_mbi = self.virtual_query(address)
if not tmp_mbi.Protect & PAGE_GUARD:
break
print "PAGE GUARD on %08x" % address
cursor += mbi.RegionSize
####################################################################################################################
def debug_active_process (self, pid):
'''
Convenience wrapper around GetLastError() and FormatMessage(). Returns the error code and formatted message
associated with the last error. You probably do not want to call this directly, rather look at attach().
@type pid: Integer
@param pid: Process ID to attach to
@raise pdx: An exception is raised on failure.
'''
if not kernel32.DebugActiveProcess(pid):
raise pdx("DebugActiveProcess(%d)" % pid, True)
####################################################################################################################
def debug_event_iteration (self):
'''
Check for and process a debug event.
'''
continue_status = DBG_CONTINUE
dbg = DEBUG_EVENT()
# wait for a debug event.
if kernel32.WaitForDebugEvent(byref(dbg), 100):
# grab various information with regards to the current exception.
self.h_thread = self.open_thread(dbg.dwThreadId)
self.context = self.get_thread_context(self.h_thread)
self.dbg = dbg
self.exception_address = dbg.u.Exception.ExceptionRecord.ExceptionAddress
self.write_violation = dbg.u.Exception.ExceptionRecord.ExceptionInformation[0]
self.violation_address = dbg.u.Exception.ExceptionRecord.ExceptionInformation[1]
self.exception_code = dbg.u.Exception.ExceptionRecord.ExceptionCode
if dbg.dwDebugEventCode == CREATE_PROCESS_DEBUG_EVENT:
continue_status = self.event_handler_create_process()
elif dbg.dwDebugEventCode == CREATE_THREAD_DEBUG_EVENT:
continue_status = self.event_handler_create_thread()
elif dbg.dwDebugEventCode == EXIT_PROCESS_DEBUG_EVENT:
continue_status = self.event_handler_exit_process()
elif dbg.dwDebugEventCode == EXIT_THREAD_DEBUG_EVENT:
continue_status = self.event_handler_exit_thread()
elif dbg.dwDebugEventCode == LOAD_DLL_DEBUG_EVENT:
continue_status = self.event_handler_load_dll()
elif dbg.dwDebugEventCode == UNLOAD_DLL_DEBUG_EVENT:
continue_status = self.event_handler_unload_dll()
# an exception was caught.
elif dbg.dwDebugEventCode == EXCEPTION_DEBUG_EVENT:
ec = dbg.u.Exception.ExceptionRecord.ExceptionCode
self._log("debug_event_loop() exception: %08x" % ec)
# call the internal handler for the exception event that just occured.
if ec == EXCEPTION_ACCESS_VIOLATION:
continue_status = self.exception_handler_access_violation()
elif ec == EXCEPTION_BREAKPOINT:
continue_status = self.exception_handler_breakpoint()
elif ec == EXCEPTION_GUARD_PAGE:
continue_status = self.exception_handler_guard_page()
elif ec == EXCEPTION_SINGLE_STEP:
continue_status = self.exception_handler_single_step()
# generic callback support.
elif self.callbacks.has_key(ec):
continue_status = self.callbacks[ec](self)
# unhandled exception.
else:
self._log("TID:%04x caused an unhandled exception (%08x) at %08x" % (self.dbg.dwThreadId, ec, self.exception_address))
continue_status = DBG_EXCEPTION_NOT_HANDLED
# if the memory space of the debuggee was tainted, flush the instruction cache.
# from MSDN: Applications should call FlushInstructionCache if they generate or modify code in memory.
# The CPU cannot detect the change, and may execute the old code it cached.
if self.dirty:
kernel32.FlushInstructionCache(self.h_process, 0, 0)
# close the opened thread handle and resume executing the thread that triggered the debug event.
self.close_handle(self.h_thread)
kernel32.ContinueDebugEvent(dbg.dwProcessId, dbg.dwThreadId, continue_status)
####################################################################################################################
def debug_event_loop (self):
'''
Enter the infinite debug event handling loop. This is the main loop of the debugger and is responsible for
catching debug events and exceptions and dispatching them appropriately. This routine will check for and call
the USER_CALLBACK_DEBUG_EVENT callback on each loop iteration. run() is an alias for this routine.
@see: run()
@raise pdx: An exception is raised on any exceptional conditions, such as debugger being interrupted or
debuggee quiting.
'''
while self.debugger_active:
# don't let the user interrupt us in the midst of handling a debug event.
try:
def_sigint_handler = None
def_sigint_handler = signal.signal(signal.SIGINT, self.sigint_handler)
except:
pass
# if a user callback was specified, call it.
if self.callbacks.has_key(USER_CALLBACK_DEBUG_EVENT):
# user callbacks do not / should not access debugger or contextual information.
self.dbg = self.context = None
self.callbacks[USER_CALLBACK_DEBUG_EVENT](self)
# iterate through a debug event.
self.debug_event_iteration()
# resume keyboard interruptability.
if def_sigint_handler:
signal.signal(signal.SIGINT, def_sigint_handler)
# close the global process handle.
self.close_handle(self.h_process)
####################################################################################################################
def debug_set_process_kill_on_exit (self, kill_on_exit):
'''
Convenience wrapper around DebugSetProcessKillOnExit().
@type kill_on_exit: Bool
@param kill_on_exit: True to kill the process on debugger exit, False to let debuggee continue running.
@raise pdx: An exception is raised on failure.
'''
if not kernel32.DebugSetProcessKillOnExit(kill_on_exit):
raise pdx("DebugActiveProcess(%s)" % kill_on_exit, True)
####################################################################################################################
def detach (self):
'''
Detach from debuggee.
@raise pdx: An exception is raised on failure.
@rtype: pydbg
@return: Self
'''
self._log("detaching from debuggee")
# remove all software, memory and hardware breakpoints.
self.bp_del_all()
self.bp_del_mem_all()
self.bp_del_hw_all()
# try to detach from the target process if the API is available on the current platform.
kernel32.DebugActiveProcessStop(self.pid)
self.set_debugger_active(False)
return self.ret_self()
####################################################################################################################
def disasm (self, address):
'''
Pydasm disassemble utility function wrapper. Stores the pydasm decoded instruction in self.instruction.
@type address: DWORD
@param address: Address to disassemble at
@rtype: String
@return: Disassembled string.