RedPanda-CPP/tools/gdb-scripts/gcc-11.2.0/python/libstdcxx/v6/xmethods.py

806 lines
28 KiB
Python
Raw Permalink Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

# Xmethods for libstdc++.
# Copyright (C) 2014-2021 Free Software Foundation, Inc.
# 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 3 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, see <http://www.gnu.org/licenses/>.
import gdb
import gdb.xmethod
import re
matcher_name_prefix = 'libstdc++::'
def get_bool_type():
return gdb.lookup_type('bool')
def get_std_size_type():
return gdb.lookup_type('std::size_t')
class LibStdCxxXMethod(gdb.xmethod.XMethod):
def __init__(self, name, worker_class):
gdb.xmethod.XMethod.__init__(self, name)
self.worker_class = worker_class
# Xmethods for std::array
class ArrayWorkerBase(gdb.xmethod.XMethodWorker):
def __init__(self, val_type, size):
self._val_type = val_type
self._size = size
def null_value(self):
nullptr = gdb.parse_and_eval('(void *) 0')
return nullptr.cast(self._val_type.pointer()).dereference()
class ArraySizeWorker(ArrayWorkerBase):
def __init__(self, val_type, size):
ArrayWorkerBase.__init__(self, val_type, size)
def get_arg_types(self):
return None
def get_result_type(self, obj):
return get_std_size_type()
def __call__(self, obj):
return self._size
class ArrayEmptyWorker(ArrayWorkerBase):
def __init__(self, val_type, size):
ArrayWorkerBase.__init__(self, val_type, size)
def get_arg_types(self):
return None
def get_result_type(self, obj):
return get_bool_type()
def __call__(self, obj):
return (int(self._size) == 0)
class ArrayFrontWorker(ArrayWorkerBase):
def __init__(self, val_type, size):
ArrayWorkerBase.__init__(self, val_type, size)
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
if int(self._size) > 0:
return obj['_M_elems'][0]
else:
return self.null_value()
class ArrayBackWorker(ArrayWorkerBase):
def __init__(self, val_type, size):
ArrayWorkerBase.__init__(self, val_type, size)
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
if int(self._size) > 0:
return obj['_M_elems'][self._size - 1]
else:
return self.null_value()
class ArrayAtWorker(ArrayWorkerBase):
def __init__(self, val_type, size):
ArrayWorkerBase.__init__(self, val_type, size)
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, index):
return self._val_type
def __call__(self, obj, index):
if int(index) >= int(self._size):
raise IndexError('Array index "%d" should not be >= %d.' %
((int(index), self._size)))
return obj['_M_elems'][index]
class ArraySubscriptWorker(ArrayWorkerBase):
def __init__(self, val_type, size):
ArrayWorkerBase.__init__(self, val_type, size)
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, index):
return self._val_type
def __call__(self, obj, index):
if int(self._size) > 0:
return obj['_M_elems'][index]
else:
return self.null_value()
class ArrayMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self):
gdb.xmethod.XMethodMatcher.__init__(self,
matcher_name_prefix + 'array')
self._method_dict = {
'size': LibStdCxxXMethod('size', ArraySizeWorker),
'empty': LibStdCxxXMethod('empty', ArrayEmptyWorker),
'front': LibStdCxxXMethod('front', ArrayFrontWorker),
'back': LibStdCxxXMethod('back', ArrayBackWorker),
'at': LibStdCxxXMethod('at', ArrayAtWorker),
'operator[]': LibStdCxxXMethod('operator[]', ArraySubscriptWorker),
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?array<.*>$', class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
try:
value_type = class_type.template_argument(0)
size = class_type.template_argument(1)
except:
return None
return method.worker_class(value_type, size)
# Xmethods for std::deque
class DequeWorkerBase(gdb.xmethod.XMethodWorker):
def __init__(self, val_type):
self._val_type = val_type
self._bufsize = 512 // val_type.sizeof or 1
def size(self, obj):
first_node = obj['_M_impl']['_M_start']['_M_node']
last_node = obj['_M_impl']['_M_finish']['_M_node']
cur = obj['_M_impl']['_M_finish']['_M_cur']
first = obj['_M_impl']['_M_finish']['_M_first']
return (last_node - first_node) * self._bufsize + (cur - first)
def index(self, obj, idx):
first_node = obj['_M_impl']['_M_start']['_M_node']
index_node = first_node + int(idx) // self._bufsize
return index_node[0][idx % self._bufsize]
class DequeEmptyWorker(DequeWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return get_bool_type()
def __call__(self, obj):
return (obj['_M_impl']['_M_start']['_M_cur'] ==
obj['_M_impl']['_M_finish']['_M_cur'])
class DequeSizeWorker(DequeWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return get_std_size_type()
def __call__(self, obj):
return self.size(obj)
class DequeFrontWorker(DequeWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
return obj['_M_impl']['_M_start']['_M_cur'][0]
class DequeBackWorker(DequeWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
if (obj['_M_impl']['_M_finish']['_M_cur'] ==
obj['_M_impl']['_M_finish']['_M_first']):
prev_node = obj['_M_impl']['_M_finish']['_M_node'] - 1
return prev_node[0][self._bufsize - 1]
else:
return obj['_M_impl']['_M_finish']['_M_cur'][-1]
class DequeSubscriptWorker(DequeWorkerBase):
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, subscript):
return self._val_type
def __call__(self, obj, subscript):
return self.index(obj, subscript)
class DequeAtWorker(DequeWorkerBase):
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, index):
return self._val_type
def __call__(self, obj, index):
deque_size = int(self.size(obj))
if int(index) >= deque_size:
raise IndexError('Deque index "%d" should not be >= %d.' %
(int(index), deque_size))
else:
return self.index(obj, index)
class DequeMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self):
gdb.xmethod.XMethodMatcher.__init__(self,
matcher_name_prefix + 'deque')
self._method_dict = {
'empty': LibStdCxxXMethod('empty', DequeEmptyWorker),
'size': LibStdCxxXMethod('size', DequeSizeWorker),
'front': LibStdCxxXMethod('front', DequeFrontWorker),
'back': LibStdCxxXMethod('back', DequeBackWorker),
'operator[]': LibStdCxxXMethod('operator[]', DequeSubscriptWorker),
'at': LibStdCxxXMethod('at', DequeAtWorker)
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?deque<.*>$', class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
return method.worker_class(class_type.template_argument(0))
# Xmethods for std::forward_list
class ForwardListWorkerBase(gdb.xmethod.XMethodMatcher):
def __init__(self, val_type, node_type):
self._val_type = val_type
self._node_type = node_type
def get_arg_types(self):
return None
class ForwardListEmptyWorker(ForwardListWorkerBase):
def get_result_type(self, obj):
return get_bool_type()
def __call__(self, obj):
return obj['_M_impl']['_M_head']['_M_next'] == 0
class ForwardListFrontWorker(ForwardListWorkerBase):
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
node = obj['_M_impl']['_M_head']['_M_next'].cast(self._node_type)
val_address = node['_M_storage']['_M_storage'].address
return val_address.cast(self._val_type.pointer()).dereference()
class ForwardListMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self):
matcher_name = matcher_name_prefix + 'forward_list'
gdb.xmethod.XMethodMatcher.__init__(self, matcher_name)
self._method_dict = {
'empty': LibStdCxxXMethod('empty', ForwardListEmptyWorker),
'front': LibStdCxxXMethod('front', ForwardListFrontWorker)
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?forward_list<.*>$', class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
val_type = class_type.template_argument(0)
node_type = gdb.lookup_type(str(class_type) + '::_Node').pointer()
return method.worker_class(val_type, node_type)
# Xmethods for std::list
class ListWorkerBase(gdb.xmethod.XMethodWorker):
def __init__(self, val_type, node_type):
self._val_type = val_type
self._node_type = node_type
def get_arg_types(self):
return None
def get_value_from_node(self, node):
node = node.dereference()
if node.type.fields()[1].name == '_M_data':
# C++03 implementation, node contains the value as a member
return node['_M_data']
# C++11 implementation, node stores value in __aligned_membuf
addr = node['_M_storage'].address
return addr.cast(self._val_type.pointer()).dereference()
class ListEmptyWorker(ListWorkerBase):
def get_result_type(self, obj):
return get_bool_type()
def __call__(self, obj):
base_node = obj['_M_impl']['_M_node']
if base_node['_M_next'] == base_node.address:
return True
else:
return False
class ListSizeWorker(ListWorkerBase):
def get_result_type(self, obj):
return get_std_size_type()
def __call__(self, obj):
begin_node = obj['_M_impl']['_M_node']['_M_next']
end_node = obj['_M_impl']['_M_node'].address
size = 0
while begin_node != end_node:
begin_node = begin_node['_M_next']
size += 1
return size
class ListFrontWorker(ListWorkerBase):
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
node = obj['_M_impl']['_M_node']['_M_next'].cast(self._node_type)
return self.get_value_from_node(node)
class ListBackWorker(ListWorkerBase):
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
prev_node = obj['_M_impl']['_M_node']['_M_prev'].cast(self._node_type)
return self.get_value_from_node(prev_node)
class ListMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self):
gdb.xmethod.XMethodMatcher.__init__(self,
matcher_name_prefix + 'list')
self._method_dict = {
'empty': LibStdCxxXMethod('empty', ListEmptyWorker),
'size': LibStdCxxXMethod('size', ListSizeWorker),
'front': LibStdCxxXMethod('front', ListFrontWorker),
'back': LibStdCxxXMethod('back', ListBackWorker)
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?(__cxx11::)?list<.*>$', class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
val_type = class_type.template_argument(0)
node_type = gdb.lookup_type(str(class_type) + '::_Node').pointer()
return method.worker_class(val_type, node_type)
# Xmethods for std::vector
class VectorWorkerBase(gdb.xmethod.XMethodWorker):
def __init__(self, val_type):
self._val_type = val_type
def size(self, obj):
if self._val_type.code == gdb.TYPE_CODE_BOOL:
start = obj['_M_impl']['_M_start']['_M_p']
finish = obj['_M_impl']['_M_finish']['_M_p']
finish_offset = obj['_M_impl']['_M_finish']['_M_offset']
bit_size = start.dereference().type.sizeof * 8
return (finish - start) * bit_size + finish_offset
else:
return obj['_M_impl']['_M_finish'] - obj['_M_impl']['_M_start']
def get(self, obj, index):
if self._val_type.code == gdb.TYPE_CODE_BOOL:
start = obj['_M_impl']['_M_start']['_M_p']
bit_size = start.dereference().type.sizeof * 8
valp = start + index // bit_size
offset = index % bit_size
return (valp.dereference() & (1 << offset)) > 0
else:
return obj['_M_impl']['_M_start'][index]
class VectorEmptyWorker(VectorWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return get_bool_type()
def __call__(self, obj):
return int(self.size(obj)) == 0
class VectorSizeWorker(VectorWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return get_std_size_type()
def __call__(self, obj):
return self.size(obj)
class VectorFrontWorker(VectorWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
return self.get(obj, 0)
class VectorBackWorker(VectorWorkerBase):
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._val_type
def __call__(self, obj):
return self.get(obj, int(self.size(obj)) - 1)
class VectorAtWorker(VectorWorkerBase):
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, index):
return self._val_type
def __call__(self, obj, index):
size = int(self.size(obj))
if int(index) >= size:
raise IndexError('Vector index "%d" should not be >= %d.' %
((int(index), size)))
return self.get(obj, int(index))
class VectorSubscriptWorker(VectorWorkerBase):
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, subscript):
return self._val_type
def __call__(self, obj, subscript):
return self.get(obj, int(subscript))
class VectorMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self):
gdb.xmethod.XMethodMatcher.__init__(self,
matcher_name_prefix + 'vector')
self._method_dict = {
'size': LibStdCxxXMethod('size', VectorSizeWorker),
'empty': LibStdCxxXMethod('empty', VectorEmptyWorker),
'front': LibStdCxxXMethod('front', VectorFrontWorker),
'back': LibStdCxxXMethod('back', VectorBackWorker),
'at': LibStdCxxXMethod('at', VectorAtWorker),
'operator[]': LibStdCxxXMethod('operator[]',
VectorSubscriptWorker),
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?vector<.*>$', class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
return method.worker_class(class_type.template_argument(0))
# Xmethods for associative containers
class AssociativeContainerWorkerBase(gdb.xmethod.XMethodWorker):
def __init__(self, unordered):
self._unordered = unordered
def node_count(self, obj):
if self._unordered:
return obj['_M_h']['_M_element_count']
else:
return obj['_M_t']['_M_impl']['_M_node_count']
def get_arg_types(self):
return None
class AssociativeContainerEmptyWorker(AssociativeContainerWorkerBase):
def get_result_type(self, obj):
return get_bool_type()
def __call__(self, obj):
return int(self.node_count(obj)) == 0
class AssociativeContainerSizeWorker(AssociativeContainerWorkerBase):
def get_result_type(self, obj):
return get_std_size_type()
def __call__(self, obj):
return self.node_count(obj)
class AssociativeContainerMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self, name):
gdb.xmethod.XMethodMatcher.__init__(self,
matcher_name_prefix + name)
self._name = name
self._method_dict = {
'size': LibStdCxxXMethod('size', AssociativeContainerSizeWorker),
'empty': LibStdCxxXMethod('empty',
AssociativeContainerEmptyWorker),
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?%s<.*>$' % self._name, class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
unordered = 'unordered' in self._name
return method.worker_class(unordered)
# Xmethods for std::unique_ptr
class UniquePtrGetWorker(gdb.xmethod.XMethodWorker):
"Implements std::unique_ptr<T>::get() and std::unique_ptr<T>::operator->()"
def __init__(self, elem_type):
self._is_array = elem_type.code == gdb.TYPE_CODE_ARRAY
if self._is_array:
self._elem_type = elem_type.target()
else:
self._elem_type = elem_type
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._elem_type.pointer()
def _supports(self, method_name):
"operator-> is not supported for unique_ptr<T[]>"
return method_name == 'get' or not self._is_array
def __call__(self, obj):
impl_type = obj.dereference().type.fields()[0].type.tag
# Check for new implementations first:
if re.match('^std::(__\d+::)?__uniq_ptr_(data|impl)<.*>$', impl_type):
tuple_member = obj['_M_t']['_M_t']
elif re.match('^std::(__\d+::)?tuple<.*>$', impl_type):
tuple_member = obj['_M_t']
else:
return None
tuple_impl_type = tuple_member.type.fields()[0].type # _Tuple_impl
tuple_head_type = tuple_impl_type.fields()[1].type # _Head_base
head_field = tuple_head_type.fields()[0]
if head_field.name == '_M_head_impl':
return tuple_member['_M_head_impl']
elif head_field.is_base_class:
return tuple_member.cast(head_field.type)
else:
return None
class UniquePtrDerefWorker(UniquePtrGetWorker):
"Implements std::unique_ptr<T>::operator*()"
def __init__(self, elem_type):
UniquePtrGetWorker.__init__(self, elem_type)
def get_result_type(self, obj):
return self._elem_type
def _supports(self, method_name):
"operator* is not supported for unique_ptr<T[]>"
return not self._is_array
def __call__(self, obj):
return UniquePtrGetWorker.__call__(self, obj).dereference()
class UniquePtrSubscriptWorker(UniquePtrGetWorker):
"Implements std::unique_ptr<T>::operator[](size_t)"
def __init__(self, elem_type):
UniquePtrGetWorker.__init__(self, elem_type)
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, index):
return self._elem_type
def _supports(self, method_name):
"operator[] is only supported for unique_ptr<T[]>"
return self._is_array
def __call__(self, obj, index):
return UniquePtrGetWorker.__call__(self, obj)[index]
class UniquePtrMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self):
gdb.xmethod.XMethodMatcher.__init__(self,
matcher_name_prefix + 'unique_ptr')
self._method_dict = {
'get': LibStdCxxXMethod('get', UniquePtrGetWorker),
'operator->': LibStdCxxXMethod('operator->', UniquePtrGetWorker),
'operator*': LibStdCxxXMethod('operator*', UniquePtrDerefWorker),
'operator[]': LibStdCxxXMethod('operator[]', UniquePtrSubscriptWorker),
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?unique_ptr<.*>$', class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
worker = method.worker_class(class_type.template_argument(0))
if worker._supports(method_name):
return worker
return None
# Xmethods for std::shared_ptr
class SharedPtrGetWorker(gdb.xmethod.XMethodWorker):
"Implements std::shared_ptr<T>::get() and std::shared_ptr<T>::operator->()"
def __init__(self, elem_type):
self._is_array = elem_type.code == gdb.TYPE_CODE_ARRAY
if self._is_array:
self._elem_type = elem_type.target()
else:
self._elem_type = elem_type
def get_arg_types(self):
return None
def get_result_type(self, obj):
return self._elem_type.pointer()
def _supports(self, method_name):
"operator-> is not supported for shared_ptr<T[]>"
return method_name == 'get' or not self._is_array
def __call__(self, obj):
return obj['_M_ptr']
class SharedPtrDerefWorker(SharedPtrGetWorker):
"Implements std::shared_ptr<T>::operator*()"
def __init__(self, elem_type):
SharedPtrGetWorker.__init__(self, elem_type)
def get_result_type(self, obj):
return self._elem_type
def _supports(self, method_name):
"operator* is not supported for shared_ptr<T[]>"
return not self._is_array
def __call__(self, obj):
return SharedPtrGetWorker.__call__(self, obj).dereference()
class SharedPtrSubscriptWorker(SharedPtrGetWorker):
"Implements std::shared_ptr<T>::operator[](size_t)"
def __init__(self, elem_type):
SharedPtrGetWorker.__init__(self, elem_type)
def get_arg_types(self):
return get_std_size_type()
def get_result_type(self, obj, index):
return self._elem_type
def _supports(self, method_name):
"operator[] is only supported for shared_ptr<T[]>"
return self._is_array
def __call__(self, obj, index):
# Check bounds if _elem_type is an array of known bound
m = re.match('.*\[(\d+)]$', str(self._elem_type))
if m and index >= int(m.group(1)):
raise IndexError('shared_ptr<%s> index "%d" should not be >= %d.' %
(self._elem_type, int(index), int(m.group(1))))
return SharedPtrGetWorker.__call__(self, obj)[index]
class SharedPtrUseCountWorker(gdb.xmethod.XMethodWorker):
"Implements std::shared_ptr<T>::use_count()"
def __init__(self, elem_type):
SharedPtrUseCountWorker.__init__(self, elem_type)
def get_arg_types(self):
return None
def get_result_type(self, obj):
return gdb.lookup_type('long')
def __call__(self, obj):
refcounts = obj['_M_refcount']['_M_pi']
return refcounts['_M_use_count'] if refcounts else 0
class SharedPtrUniqueWorker(SharedPtrUseCountWorker):
"Implements std::shared_ptr<T>::unique()"
def __init__(self, elem_type):
SharedPtrUseCountWorker.__init__(self, elem_type)
def get_result_type(self, obj):
return gdb.lookup_type('bool')
def __call__(self, obj):
return SharedPtrUseCountWorker.__call__(self, obj) == 1
class SharedPtrMethodsMatcher(gdb.xmethod.XMethodMatcher):
def __init__(self):
gdb.xmethod.XMethodMatcher.__init__(self,
matcher_name_prefix + 'shared_ptr')
self._method_dict = {
'get': LibStdCxxXMethod('get', SharedPtrGetWorker),
'operator->': LibStdCxxXMethod('operator->', SharedPtrGetWorker),
'operator*': LibStdCxxXMethod('operator*', SharedPtrDerefWorker),
'operator[]': LibStdCxxXMethod('operator[]', SharedPtrSubscriptWorker),
'use_count': LibStdCxxXMethod('use_count', SharedPtrUseCountWorker),
'unique': LibStdCxxXMethod('unique', SharedPtrUniqueWorker),
}
self.methods = [self._method_dict[m] for m in self._method_dict]
def match(self, class_type, method_name):
if not re.match('^std::(__\d+::)?shared_ptr<.*>$', class_type.tag):
return None
method = self._method_dict.get(method_name)
if method is None or not method.enabled:
return None
worker = method.worker_class(class_type.template_argument(0))
if worker._supports(method_name):
return worker
return None
def register_libstdcxx_xmethods(locus):
gdb.xmethod.register_xmethod_matcher(locus, ArrayMethodsMatcher())
gdb.xmethod.register_xmethod_matcher(locus, ForwardListMethodsMatcher())
gdb.xmethod.register_xmethod_matcher(locus, DequeMethodsMatcher())
gdb.xmethod.register_xmethod_matcher(locus, ListMethodsMatcher())
gdb.xmethod.register_xmethod_matcher(locus, VectorMethodsMatcher())
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('set'))
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('map'))
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('multiset'))
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('multimap'))
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('unordered_set'))
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('unordered_map'))
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('unordered_multiset'))
gdb.xmethod.register_xmethod_matcher(
locus, AssociativeContainerMethodsMatcher('unordered_multimap'))
gdb.xmethod.register_xmethod_matcher(locus, UniquePtrMethodsMatcher())
gdb.xmethod.register_xmethod_matcher(locus, SharedPtrMethodsMatcher())