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#
# gdb helper commands and functions for Linux kernel debugging
#
# common utilities
#
# Copyright (c) Siemens AG, 2011-2013
#
# Authors:
# Jan Kiszka <jan.kiszka@siemens.com>
#
# This work is licensed under the terms of the GNU GPL version 2.
#
import gdb
class CachedType:
def __init__(self, name):
self._type = None
self._name = name
def _new_objfile_handler(self, event):
self._type = None
gdb.events.new_objfile.disconnect(self._new_objfile_handler)
def get_type(self):
if self._type is None:
self._type = gdb.lookup_type(self._name)
if self._type is None:
raise gdb.GdbError(
"cannot resolve type '{0}'".format(self._name))
if hasattr(gdb, 'events') and hasattr(gdb.events, 'new_objfile'):
gdb.events.new_objfile.connect(self._new_objfile_handler)
return self._type
long_type = CachedType("long")
atomic_long_type = CachedType("atomic_long_t")
def get_long_type():
global long_type
return long_type.get_type()
def offset_of(typeobj, field):
element = gdb.Value(0).cast(typeobj)
return int(str(element[field].address).split()[0], 16)
def container_of(ptr, typeobj, member):
return (ptr.cast(get_long_type()) -
offset_of(typeobj, member)).cast(typeobj)
class ContainerOf(gdb.Function):
"""Return pointer to containing data structure.
$container_of(PTR, "TYPE", "ELEMENT"): Given PTR, return a pointer to the
data structure of the type TYPE in which PTR is the address of ELEMENT.
Note that TYPE and ELEMENT have to be quoted as strings."""
def __init__(self):
super(ContainerOf, self).__init__("container_of")
def invoke(self, ptr, typename, elementname):
return container_of(ptr, gdb.lookup_type(typename.string()).pointer(),
elementname.string())
ContainerOf()
BIG_ENDIAN = 0
LITTLE_ENDIAN = 1
target_endianness = None
def get_target_endianness():
global target_endianness
if target_endianness is None:
endian = gdb.execute("show endian", to_string=True)
if "little endian" in endian:
target_endianness = LITTLE_ENDIAN
elif "big endian" in endian:
target_endianness = BIG_ENDIAN
else:
raise gdb.GdbError("unknown endianness '{0}'".format(str(endian)))
return target_endianness
def read_memoryview(inf, start, length):
m = inf.read_memory(start, length)
if type(m) is memoryview:
return m
return memoryview(m)
def read_u16(buffer, offset):
buffer_val = buffer[offset:offset + 2]
value = [0, 0]
if type(buffer_val[0]) is str:
value[0] = ord(buffer_val[0])
value[1] = ord(buffer_val[1])
else:
value[0] = buffer_val[0]
value[1] = buffer_val[1]
if get_target_endianness() == LITTLE_ENDIAN:
return value[0] + (value[1] << 8)
else:
return value[1] + (value[0] << 8)
def read_u32(buffer, offset):
if get_target_endianness() == LITTLE_ENDIAN:
return read_u16(buffer, offset) + (read_u16(buffer, offset + 2) << 16)
else:
return read_u16(buffer, offset + 2) + (read_u16(buffer, offset) << 16)
def read_u64(buffer, offset):
if get_target_endianness() == LITTLE_ENDIAN:
return read_u32(buffer, offset) + (read_u32(buffer, offset + 4) << 32)
else:
return read_u32(buffer, offset + 4) + (read_u32(buffer, offset) << 32)
def read_ulong(buffer, offset):
if get_long_type().sizeof == 8:
return read_u64(buffer, offset)
else:
return read_u32(buffer, offset)
atomic_long_counter_offset = atomic_long_type.get_type()['counter'].bitpos
atomic_long_counter_sizeof = atomic_long_type.get_type()['counter'].type.sizeof
def read_atomic_long(buffer, offset):
global atomic_long_counter_offset
global atomic_long_counter_sizeof
if atomic_long_counter_sizeof == 8:
return read_u64(buffer, offset + atomic_long_counter_offset)
else:
return read_u32(buffer, offset + atomic_long_counter_offset)
target_arch = None
def is_target_arch(arch):
if hasattr(gdb.Frame, 'architecture'):
return arch in gdb.newest_frame().architecture().name()
else:
global target_arch
if target_arch is None:
target_arch = gdb.execute("show architecture", to_string=True)
return arch in target_arch
GDBSERVER_QEMU = 0
GDBSERVER_KGDB = 1
gdbserver_type = None
def get_gdbserver_type():
def exit_handler(event):
global gdbserver_type
gdbserver_type = None
gdb.events.exited.disconnect(exit_handler)
def probe_qemu():
try:
return gdb.execute("monitor info version", to_string=True) != ""
except gdb.error:
return False
def probe_kgdb():
try:
thread_info = gdb.execute("info thread 2", to_string=True)
return "shadowCPU0" in thread_info
except gdb.error:
return False
global gdbserver_type
if gdbserver_type is None:
if probe_qemu():
gdbserver_type = GDBSERVER_QEMU
elif probe_kgdb():
gdbserver_type = GDBSERVER_KGDB
if gdbserver_type is not None and hasattr(gdb, 'events'):
gdb.events.exited.connect(exit_handler)
return gdbserver_type
def gdb_eval_or_none(expresssion):
try:
return gdb.parse_and_eval(expresssion)
except gdb.error:
return None
def dentry_name(d):
parent = d['d_parent']
if parent == d or parent == 0:
return ""
p = dentry_name(d['d_parent']) + "/"
return p + d['d_iname'].string()
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