# Pretty-printers for libstc++. # Copyright (C) 2008, 2009, 2010 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 itertools import re class StdPointerPrinter: "Print a smart pointer of some kind" def __init__ (self, typename, val): self.typename = typename self.val = val def to_string (self): if self.val['_M_refcount']['_M_pi'] == 0: return '%s (empty) %s' % (self.typename, self.val['_M_ptr']) return '%s (count %d) %s' % (self.typename, self.val['_M_refcount']['_M_pi']['_M_use_count'], self.val['_M_ptr']) class UniquePointerPrinter: "Print a unique_ptr" def __init__ (self, val): self.val = val def to_string (self): return self.val['_M_t'] class StdListPrinter: "Print a std::list" class _iterator: def __init__(self, nodetype, head): self.nodetype = nodetype self.base = head['_M_next'] self.head = head.address self.count = 0 def __iter__(self): return self def next(self): if self.base == self.head: raise StopIteration elt = self.base.cast(self.nodetype).dereference() self.base = elt['_M_next'] count = self.count self.count = self.count + 1 return ('[%d]' % count, elt['_M_data']) def __init__(self, typename, val): self.typename = typename self.val = val def children(self): itype = self.val.type.template_argument(0) # If the inferior program is compiled with -D_GLIBCXX_DEBUG # some of the internal implementation details change. if self.typename == "std::list": nodetype = gdb.lookup_type('std::_List_node<%s>' % itype).pointer() elif self.typename == "std::__debug::list": nodetype = gdb.lookup_type('std::__norm::_List_node<%s>' % itype).pointer() else: raise ValueError, "Cannot cast list node for list printer." return self._iterator(nodetype, self.val['_M_impl']['_M_node']) def to_string(self): if self.val['_M_impl']['_M_node'].address == self.val['_M_impl']['_M_node']['_M_next']: return 'empty %s' % (self.typename) return '%s' % (self.typename) class StdListIteratorPrinter: "Print std::list::iterator" def __init__(self, typename, val): self.val = val self.typename = typename def to_string(self): itype = self.val.type.template_argument(0) # If the inferior program is compiled with -D_GLIBCXX_DEBUG # some of the internal implementation details change. if self.typename == "std::_List_iterator" or self.typename == "std::_List_const_iterator": nodetype = gdb.lookup_type('std::_List_node<%s>' % itype).pointer() elif self.typename == "std::__norm::_List_iterator" or self.typename == "std::__norm::_List_const_iterator": nodetype = gdb.lookup_type('std::__norm::_List_node<%s>' % itype).pointer() else: raise ValueError, "Cannot cast list node for list iterator printer." return self.val['_M_node'].cast(nodetype).dereference()['_M_data'] class StdSlistPrinter: "Print a __gnu_cxx::slist" class _iterator: def __init__(self, nodetype, head): self.nodetype = nodetype self.base = head['_M_head']['_M_next'] self.count = 0 def __iter__(self): return self def next(self): if self.base == 0: raise StopIteration elt = self.base.cast(self.nodetype).dereference() self.base = elt['_M_next'] count = self.count self.count = self.count + 1 return ('[%d]' % count, elt['_M_data']) def __init__(self, val): self.val = val def children(self): itype = self.val.type.template_argument(0) nodetype = gdb.lookup_type('__gnu_cxx::_Slist_node<%s>' % itype).pointer() return self._iterator(nodetype, self.val) def to_string(self): if self.val['_M_head']['_M_next'] == 0: return 'empty __gnu_cxx::slist' return '__gnu_cxx::slist' class StdSlistIteratorPrinter: "Print __gnu_cxx::slist::iterator" def __init__(self, val): self.val = val def to_string(self): itype = self.val.type.template_argument(0) nodetype = gdb.lookup_type('__gnu_cxx::_Slist_node<%s>' % itype).pointer() return self.val['_M_node'].cast(nodetype).dereference()['_M_data'] class StdVectorPrinter: "Print a std::vector" class _iterator: def __init__ (self, start, finish, bitvec): self.bitvec = bitvec if bitvec: self.item = start['_M_p'] self.so = start['_M_offset'] self.finish = finish['_M_p'] self.fo = finish['_M_offset'] itype = self.item.dereference().type self.isize = 8 * itype.sizeof else: self.item = start self.finish = finish self.count = 0 def __iter__(self): return self def next(self): count = self.count self.count = self.count + 1 if self.bitvec: if self.item == self.finish and self.so >= self.fo: raise StopIteration elt = self.item.dereference() if elt & (1 << self.so): obit = 1 else: obit = 0 self.so = self.so + 1 if self.so >= self.isize: self.item = self.item + 1 self.so = 0 return ('[%d]' % count, obit) else: if self.item == self.finish: raise StopIteration elt = self.item.dereference() self.item = self.item + 1 return ('[%d]' % count, elt) def __init__(self, typename, val): self.typename = typename self.val = val self.is_bool = val.type.template_argument(0).code == gdb.TYPE_CODE_BOOL def children(self): return self._iterator(self.val['_M_impl']['_M_start'], self.val['_M_impl']['_M_finish'], self.is_bool) def to_string(self): start = self.val['_M_impl']['_M_start'] finish = self.val['_M_impl']['_M_finish'] end = self.val['_M_impl']['_M_end_of_storage'] if self.is_bool: start = self.val['_M_impl']['_M_start']['_M_p'] so = self.val['_M_impl']['_M_start']['_M_offset'] finish = self.val['_M_impl']['_M_finish']['_M_p'] fo = self.val['_M_impl']['_M_finish']['_M_offset'] itype = start.dereference().type bl = 8 * itype.sizeof length = (bl - so) + bl * ((finish - start) - 1) + fo capacity = bl * (end - start) return ('%s<bool> of length %d, capacity %d' % (self.typename, int (length), int (capacity))) else: return ('%s of length %d, capacity %d' % (self.typename, int (finish - start), int (end - start))) def display_hint(self): return 'array' class StdVectorIteratorPrinter: "Print std::vector::iterator" def __init__(self, val): self.val = val def to_string(self): return self.val['_M_current'].dereference() class StdTuplePrinter: "Print a std::tuple" class _iterator: def __init__ (self, head): self.head = head # Set the base class as the initial head of the # tuple. nodes = self.head.type.fields () if len (nodes) != 1: raise ValueError, "Top of tuple tree does not consist of a single node." # Set the actual head to the first pair. self.head = self.head.cast (nodes[0].type) self.count = 0 def __iter__ (self): return self def next (self): nodes = self.head.type.fields () # Check for further recursions in the inheritance tree. if len (nodes) == 0: raise StopIteration # Check that this iteration has an expected structure. if len (nodes) != 2: raise ValueError, "Cannot parse more than 2 nodes in a tuple tree." # - Left node is the next recursion parent. # - Right node is the actual class contained in the tuple. # Process right node. impl = self.head.cast (nodes[1].type) # Process left node and set it as head. self.head = self.head.cast (nodes[0].type) self.count = self.count + 1 # Finally, check the implementation. If it is # wrapped in _M_head_impl return that, otherwise return # the value "as is". fields = impl.type.fields () if len (fields) < 1 or fields[0].name != "_M_head_impl": return ('[%d]' % self.count, impl) else: return ('[%d]' % self.count, impl['_M_head_impl']) def __init__ (self, typename, val): self.typename = typename self.val = val; def children (self): return self._iterator (self.val) def to_string (self): return '%s containing' % (self.typename) class StdStackOrQueuePrinter: "Print a std::stack or std::queue" def __init__ (self, typename, val): self.typename = typename self.visualizer = gdb.default_visualizer(val['c']) def children (self): return self.visualizer.children() def to_string (self): return '%s wrapping: %s' % (self.typename, self.visualizer.to_string()) def display_hint (self): if hasattr (self.visualizer, 'display_hint'): return self.visualizer.display_hint () return None class RbtreeIterator: def __init__(self, rbtree): self.size = rbtree['_M_t']['_M_impl']['_M_node_count'] self.node = rbtree['_M_t']['_M_impl']['_M_header']['_M_left'] self.count = 0 def __iter__(self): return self def __len__(self): return int (self.size) def next(self): if self.count == self.size: raise StopIteration result = self.node self.count = self.count + 1 if self.count < self.size: # Compute the next node. node = self.node if node.dereference()['_M_right']: node = node.dereference()['_M_right'] while node.dereference()['_M_left']: node = node.dereference()['_M_left'] else: parent = node.dereference()['_M_parent'] while node == parent.dereference()['_M_right']: node = parent parent = parent.dereference()['_M_parent'] if node.dereference()['_M_right'] != parent: node = parent self.node = node return result # This is a pretty printer for std::_Rb_tree_iterator (which is # std::map::iterator), and has nothing to do with the RbtreeIterator # class above. class StdRbtreeIteratorPrinter: "Print std::map::iterator" def __init__ (self, val): self.val = val def to_string (self): valuetype = self.val.type.template_argument(0) nodetype = gdb.lookup_type('std::_Rb_tree_node < %s >' % valuetype) nodetype = nodetype.pointer() return self.val.cast(nodetype).dereference()['_M_value_field'] class StdDebugIteratorPrinter: "Print a debug enabled version of an iterator" def __init__ (self, val): self.val = val # Just strip away the encapsulating __gnu_debug::_Safe_iterator # and return the wrapped iterator value. def to_string (self): itype = self.val.type.template_argument(0) return self.val['_M_current'].cast(itype) class StdMapPrinter: "Print a std::map or std::multimap" # Turn an RbtreeIterator into a pretty-print iterator. class _iter: def __init__(self, rbiter, type): self.rbiter = rbiter self.count = 0 self.type = type def __iter__(self): return self def next(self): if self.count % 2 == 0: n = self.rbiter.next() n = n.cast(self.type).dereference()['_M_value_field'] self.pair = n item = n['first'] else: item = self.pair['second'] result = ('[%d]' % self.count, item) self.count = self.count + 1 return result def __init__ (self, typename, val): self.typename = typename self.val = val def to_string (self): return '%s with %d elements' % (self.typename, len (RbtreeIterator (self.val))) def children (self): keytype = self.val.type.template_argument(0).const() valuetype = self.val.type.template_argument(1) nodetype = gdb.lookup_type('std::_Rb_tree_node< std::pair< %s, %s > >' % (keytype, valuetype)) nodetype = nodetype.pointer() return self._iter (RbtreeIterator (self.val), nodetype) def display_hint (self): return 'map' class StdSetPrinter: "Print a std::set or std::multiset" # Turn an RbtreeIterator into a pretty-print iterator. class _iter: def __init__(self, rbiter, type): self.rbiter = rbiter self.count = 0 self.type = type def __iter__(self): return self def next(self): item = self.rbiter.next() item = item.cast(self.type).dereference()['_M_value_field'] # FIXME: this is weird ... what to do? # Maybe a 'set' display hint? result = ('[%d]' % self.count, item) self.count = self.count + 1 return result def __init__ (self, typename, val): self.typename = typename self.val = val def to_string (self): return '%s with %d elements' % (self.typename, len (RbtreeIterator (self.val))) def children (self): keytype = self.val.type.template_argument(0) nodetype = gdb.lookup_type('std::_Rb_tree_node< %s >' % keytype).pointer() return self._iter (RbtreeIterator (self.val), nodetype) class StdBitsetPrinter: "Print a std::bitset" def __init__(self, typename, val): self.typename = typename self.val = val def to_string (self): # If template_argument handled values, we could print the # size. Or we could use a regexp on the type. return '%s' % (self.typename) def children (self): words = self.val['_M_w'] wtype = words.type # The _M_w member can be either an unsigned long, or an # array. This depends on the template specialization used. # If it is a single long, convert to a single element list. if wtype.code == gdb.TYPE_CODE_ARRAY: tsize = wtype.target ().sizeof else: words = [words] tsize = wtype.sizeof nwords = wtype.sizeof / tsize result = [] byte = 0 while byte < nwords: w = words[byte] bit = 0 while w != 0: if (w & 1) != 0: # Another spot where we could use 'set'? result.append(('[%d]' % (byte * tsize * 8 + bit), 1)) bit = bit + 1 w = w >> 1 byte = byte + 1 return result class StdDequePrinter: "Print a std::deque" class _iter: def __init__(self, node, start, end, last, buffer_size): self.node = node self.p = start self.end = end self.last = last self.buffer_size = buffer_size self.count = 0 def __iter__(self): return self def next(self): if self.p == self.last: raise StopIteration result = ('[%d]' % self.count, self.p.dereference()) self.count = self.count + 1 # Advance the 'cur' pointer. self.p = self.p + 1 if self.p == self.end: # If we got to the end of this bucket, move to the # next bucket. self.node = self.node + 1 self.p = self.node[0] self.end = self.p + self.buffer_size return result def __init__(self, typename, val): self.typename = typename self.val = val self.elttype = val.type.template_argument(0) size = self.elttype.sizeof if size < 512: self.buffer_size = int (512 / size) else: self.buffer_size = 1 def to_string(self): start = self.val['_M_impl']['_M_start'] end = self.val['_M_impl']['_M_finish'] delta_n = end['_M_node'] - start['_M_node'] - 1 delta_s = start['_M_last'] - start['_M_cur'] delta_e = end['_M_cur'] - end['_M_first'] size = self.buffer_size * delta_n + delta_s + delta_e return '%s with %d elements' % (self.typename, long (size)) def children(self): start = self.val['_M_impl']['_M_start'] end = self.val['_M_impl']['_M_finish'] return self._iter(start['_M_node'], start['_M_cur'], start['_M_last'], end['_M_cur'], self.buffer_size) def display_hint (self): return 'array' class StdDequeIteratorPrinter: "Print std::deque::iterator" def __init__(self, val): self.val = val def to_string(self): return self.val['_M_cur'].dereference() class StdStringPrinter: "Print a std::basic_string of some kind" def __init__(self, val): self.val = val def to_string(self): # Make sure &string works, too. type = self.val.type if type.code == gdb.TYPE_CODE_REF: type = type.target () # Calculate the length of the string so that to_string returns # the string according to length, not according to first null # encountered. ptr = self.val ['_M_dataplus']['_M_p'] realtype = type.unqualified ().strip_typedefs () reptype = gdb.lookup_type (str (realtype) + '::_Rep').pointer () header = ptr.cast(reptype) - 1 len = header.dereference ()['_M_length'] if hasattr(ptr, "lazy_string"): return ptr.lazy_string (length = len) return ptr.string (length = len) def display_hint (self): return 'string' class Tr1HashtableIterator: def __init__ (self, hash): self.count = 0 self.n_buckets = hash['_M_element_count'] if self.n_buckets == 0: self.node = False else: self.bucket = hash['_M_buckets'] self.node = self.bucket[0] self.update () def __iter__ (self): return self def update (self): # If we advanced off the end of the chain, move to the next # bucket. while self.node == 0: self.bucket = self.bucket + 1 self.node = self.bucket[0] # If we advanced off the end of the bucket array, then # we're done. if self.count == self.n_buckets: self.node = False else: self.count = self.count + 1 def next (self): if not self.node: raise StopIteration result = self.node.dereference()['_M_v'] self.node = self.node.dereference()['_M_next'] self.update () return result class Tr1UnorderedSetPrinter: "Print a tr1::unordered_set" def __init__ (self, typename, val): self.typename = typename self.val = val def to_string (self): return '%s with %d elements' % (self.typename, self.val['_M_element_count']) @staticmethod def format_count (i): return '[%d]' % i def children (self): counter = itertools.imap (self.format_count, itertools.count()) return itertools.izip (counter, Tr1HashtableIterator (self.val)) class Tr1UnorderedMapPrinter: "Print a tr1::unordered_map" def __init__ (self, typename, val): self.typename = typename self.val = val def to_string (self): return '%s with %d elements' % (self.typename, self.val['_M_element_count']) @staticmethod def flatten (list): for elt in list: for i in elt: yield i @staticmethod def format_one (elt): return (elt['first'], elt['second']) @staticmethod def format_count (i): return '[%d]' % i def children (self): counter = itertools.imap (self.format_count, itertools.count()) # Map over the hash table and flatten the result. data = self.flatten (itertools.imap (self.format_one, Tr1HashtableIterator (self.val))) # Zip the two iterators together. return itertools.izip (counter, data) def display_hint (self): return 'map' def register_libstdcxx_printers (obj): "Register libstdc++ pretty-printers with objfile Obj." if obj == None: obj = gdb obj.pretty_printers.append (lookup_function) def lookup_function (val): "Look-up and return a pretty-printer that can print val." # Get the type. type = val.type # If it points to a reference, get the reference. if type.code == gdb.TYPE_CODE_REF: type = type.target () # Get the unqualified type, stripped of typedefs. type = type.unqualified ().strip_typedefs () # Get the type name. typename = type.tag if typename == None: return None # Iterate over local dictionary of types to determine # if a printer is registered for that type. Return an # instantiation of the printer if found. for function in pretty_printers_dict: if function.search (typename): return pretty_printers_dict[function] (val) # Cannot find a pretty printer. Return None. return None def build_libstdcxx_dictionary (): # libstdc++ objects requiring pretty-printing. # In order from: # http://gcc.gnu.org/onlinedocs/libstdc++/latest-doxygen/a01847.html pretty_printers_dict[re.compile('^std::basic_string<.*>$')] = lambda val: StdStringPrinter(val) pretty_printers_dict[re.compile('^std::bitset<.*>$')] = lambda val: StdBitsetPrinter("std::bitset", val) pretty_printers_dict[re.compile('^std::deque<.*>$')] = lambda val: StdDequePrinter("std::deque", val) pretty_printers_dict[re.compile('^std::list<.*>$')] = lambda val: StdListPrinter("std::list", val) pretty_printers_dict[re.compile('^std::map<.*>$')] = lambda val: StdMapPrinter("std::map", val) pretty_printers_dict[re.compile('^std::multimap<.*>$')] = lambda val: StdMapPrinter("std::multimap", val) pretty_printers_dict[re.compile('^std::multiset<.*>$')] = lambda val: StdSetPrinter("std::multiset", val) pretty_printers_dict[re.compile('^std::priority_queue<.*>$')] = lambda val: StdStackOrQueuePrinter("std::priority_queue", val) pretty_printers_dict[re.compile('^std::queue<.*>$')] = lambda val: StdStackOrQueuePrinter("std::queue", val) pretty_printers_dict[re.compile('^std::tuple<.*>$')] = lambda val: StdTuplePrinter("std::tuple", val) pretty_printers_dict[re.compile('^std::set<.*>$')] = lambda val: StdSetPrinter("std::set", val) pretty_printers_dict[re.compile('^std::stack<.*>$')] = lambda val: StdStackOrQueuePrinter("std::stack", val) pretty_printers_dict[re.compile('^std::unique_ptr<.*>$')] = UniquePointerPrinter pretty_printers_dict[re.compile('^std::vector<.*>$')] = lambda val: StdVectorPrinter("std::vector", val) # vector<bool> # Printer registrations for classes compiled with -D_GLIBCXX_DEBUG. pretty_printers_dict[re.compile('^std::__debug::bitset<.*>$')] = lambda val: StdBitsetPrinter("std::__debug::bitset", val) pretty_printers_dict[re.compile('^std::__debug::deque<.*>$')] = lambda val: StdDequePrinter("std::__debug::deque", val) pretty_printers_dict[re.compile('^std::__debug::list<.*>$')] = lambda val: StdListPrinter("std::__debug::list", val) pretty_printers_dict[re.compile('^std::__debug::map<.*>$')] = lambda val: StdMapPrinter("std::__debug::map", val) pretty_printers_dict[re.compile('^std::__debug::multimap<.*>$')] = lambda val: StdMapPrinter("std::__debug::multimap", val) pretty_printers_dict[re.compile('^std::__debug::multiset<.*>$')] = lambda val: StdSetPrinter("std::__debug::multiset", val) pretty_printers_dict[re.compile('^std::__debug::priority_queue<.*>$')] = lambda val: StdStackOrQueuePrinter("std::__debug::priority_queue", val) pretty_printers_dict[re.compile('^std::__debug::queue<.*>$')] = lambda val: StdStackOrQueuePrinter("std::__debug::queue", val) pretty_printers_dict[re.compile('^std::__debug::set<.*>$')] = lambda val: StdSetPrinter("std::__debug::set", val) pretty_printers_dict[re.compile('^std::__debug::stack<.*>$')] = lambda val: StdStackOrQueuePrinter("std::__debug::stack", val) pretty_printers_dict[re.compile('^std::__debug::unique_ptr<.*>$')] = UniquePointerPrinter pretty_printers_dict[re.compile('^std::__debug::vector<.*>$')] = lambda val: StdVectorPrinter("std::__debug::vector", val) # These are the TR1 and C++0x printers. # For array - the default GDB pretty-printer seems reasonable. pretty_printers_dict[re.compile('^std::shared_ptr<.*>$')] = lambda val: StdPointerPrinter ('std::shared_ptr', val) pretty_printers_dict[re.compile('^std::weak_ptr<.*>$')] = lambda val: StdPointerPrinter ('std::weak_ptr', val) pretty_printers_dict[re.compile('^std::unordered_map<.*>$')] = lambda val: Tr1UnorderedMapPrinter ('std::unordered_map', val) pretty_printers_dict[re.compile('^std::unordered_set<.*>$')] = lambda val: Tr1UnorderedSetPrinter ('std::unordered_set', val) pretty_printers_dict[re.compile('^std::unordered_multimap<.*>$')] = lambda val: Tr1UnorderedMapPrinter ('std::unordered_multimap', val) pretty_printers_dict[re.compile('^std::unordered_multiset<.*>$')] = lambda val: Tr1UnorderedSetPrinter ('std::unordered_multiset', val) pretty_printers_dict[re.compile('^std::tr1::shared_ptr<.*>$')] = lambda val: StdPointerPrinter ('std::tr1::shared_ptr', val) pretty_printers_dict[re.compile('^std::tr1::weak_ptr<.*>$')] = lambda val: StdPointerPrinter ('std::tr1::weak_ptr', val) pretty_printers_dict[re.compile('^std::tr1::unordered_map<.*>$')] = lambda val: Tr1UnorderedMapPrinter ('std::tr1::unordered_map', val) pretty_printers_dict[re.compile('^std::tr1::unordered_set<.*>$')] = lambda val: Tr1UnorderedSetPrinter ('std::tr1::unordered_set', val) pretty_printers_dict[re.compile('^std::tr1::unordered_multimap<.*>$')] = lambda val: Tr1UnorderedMapPrinter ('std::tr1::unordered_multimap', val) pretty_printers_dict[re.compile('^std::tr1::unordered_multiset<.*>$')] = lambda val: Tr1UnorderedSetPrinter ('std::tr1::unordered_multiset', val) # These are the C++0x printer registrations for -D_GLIBCXX_DEBUG cases. # The tr1 namespace printers do not seem to have any debug # equivalents, so do no register them. pretty_printers_dict[re.compile('^std::__debug::unordered_map<.*>$')] = lambda val: Tr1UnorderedMapPrinter ('std::__debug::unordered_map', val) pretty_printers_dict[re.compile('^std::__debug::unordered_set<.*>$')] = lambda val: Tr1UnorderedSetPrinter ('std::__debug::unordered_set', val) pretty_printers_dict[re.compile('^std::__debug::unordered_multimap<.*>$')] = lambda val: Tr1UnorderedMapPrinter ('std::__debug::unordered_multimap', val) pretty_printers_dict[re.compile('^std::__debug::unordered_multiset<.*>$')] = lambda val: Tr1UnorderedSetPrinter ('std::__debug:unordered_multiset', val) # Extensions. pretty_printers_dict[re.compile('^__gnu_cxx::slist<.*>$')] = StdSlistPrinter if True: # These shouldn't be necessary, if GDB "print *i" worked. # But it often doesn't, so here they are. pretty_printers_dict[re.compile('^std::_List_iterator<.*>$')] = lambda val: StdListIteratorPrinter("std::_List_iterator",val) pretty_printers_dict[re.compile('^std::_List_const_iterator<.*>$')] = lambda val: StdListIteratorPrinter("std::_List_const_iterator",val) pretty_printers_dict[re.compile('^std::_Rb_tree_iterator<.*>$')] = lambda val: StdRbtreeIteratorPrinter(val) pretty_printers_dict[re.compile('^std::_Rb_tree_const_iterator<.*>$')] = lambda val: StdRbtreeIteratorPrinter(val) pretty_printers_dict[re.compile('^std::_Deque_iterator<.*>$')] = lambda val: StdDequeIteratorPrinter(val) pretty_printers_dict[re.compile('^std::_Deque_const_iterator<.*>$')] = lambda val: StdDequeIteratorPrinter(val) pretty_printers_dict[re.compile('^__gnu_cxx::__normal_iterator<.*>$')] = lambda val: StdVectorIteratorPrinter(val) pretty_printers_dict[re.compile('^__gnu_cxx::_Slist_iterator<.*>$')] = lambda val: StdSlistIteratorPrinter(val) # Debug (compiled with -D_GLIBCXX_DEBUG) printer registrations. # The Rb_tree debug iterator when unwrapped from the encapsulating __gnu_debug::_Safe_iterator # does not have the __norm namespace. Just use the existing printer registration for that. pretty_printers_dict[re.compile('^__gnu_debug::_Safe_iterator<.*>$')] = lambda val: StdDebugIteratorPrinter(val) pretty_printers_dict[re.compile('^std::__norm::_List_iterator<.*>$')] = lambda val: StdListIteratorPrinter ("std::__norm::_List_iterator",val) pretty_printers_dict[re.compile('^std::__norm::_List_const_iterator<.*>$')] = lambda val: StdListIteratorPrinter ("std::__norm::_List_const_iterator",val) pretty_printers_dict[re.compile('^std::__norm::_Deque_const_iterator<.*>$')] = lambda val: StdDequeIteratorPrinter(val) pretty_printers_dict[re.compile('^std::__norm::_Deque_iterator<.*>$')] = lambda val: StdDequeIteratorPrinter(val) pretty_printers_dict = {} build_libstdcxx_dictionary ()