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binutils-gdb/gdb/contrib/cleanup_check.py

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Update Copyright year range in all files maintained by GDB.
2014-01-01 04:54:24 +01:00
# Copyright 2013-2014 Free Software Foundation, Inc.
add the cleanup checker This patch adds the cleanup checker. This is a Python plugin for GCC that checks some rules for cleanup handling. In particular it tries to notice when cleanups are left dangling at the end of a function. It does this by applying a few simple rules. First, it understands that a function whose return type is "struct cleanup *" is a "cleanup constructor". Such functions are expected to return the first cleanup that they make. Then, it has the notion of a "master cleanup". The checker keeps a stack of all cleanups made in a basic block. The first element is pushed on the stack is the master cleanup -- the one that must later be passed to either do_cleanups or discard_cleanups. It is not perfect -- some constructs confuse it. So, part of this series rewrites some code in gdb so that it is analyzable. I'll note these spots and you can decide whether or not this is a good idea. This patch also changes gcc-with-excheck to give it options. Now you must use either -Xc (for the cleanup checker) or -Xx (for the exception checker). * contrib/cleanup_check.py: New file. * contrib/gcc-with-excheck: Add option parsing.
2013-05-30 18:22:06 +02:00
#
# This 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 gcc
import gccutils
import sys
want_raii_info = False
logging = False
show_cfg = False
def log(msg, indent=0):
global logging
if logging:
sys.stderr.write('%s%s\n' % (' ' * indent, msg))
sys.stderr.flush()
def is_cleanup_type(return_type):
if not isinstance(return_type, gcc.PointerType):
return False
if not isinstance(return_type.dereference, gcc.RecordType):
return False
if str(return_type.dereference.name) == 'cleanup':
return True
return False
def is_constructor(decl):
"Return True if the function DECL is a cleanup constructor; False otherwise"
return is_cleanup_type(decl.type.type) and (not decl.name or str(decl.name) != 'make_final_cleanup')
destructor_names = set(['do_cleanups', 'discard_cleanups'])
def is_destructor(decl):
return decl.name in destructor_names
# This list is just much too long... we should probably have an
# attribute instead.
special_names = set(['do_final_cleanups', 'discard_final_cleanups',
'save_cleanups', 'save_final_cleanups',
'restore_cleanups', 'restore_final_cleanups',
'exceptions_state_mc_init',
'make_my_cleanup2', 'make_final_cleanup', 'all_cleanups',
'save_my_cleanups', 'quit_target'])
def needs_special_treatment(decl):
return decl.name in special_names
# Sometimes we need a new placeholder object that isn't the same as
# anything else.
class Dummy(object):
def __init__(self, location):
self.location = location
# A wrapper for a cleanup which has been assigned to a variable.
# This holds the variable and the location.
class Cleanup(object):
def __init__(self, var, location):
self.var = var
self.location = location
# A class representing a master cleanup. This holds a stack of
# cleanup objects and supports a merging operation.
class MasterCleanup(object):
# Create a new MasterCleanup object. OTHER, if given, is a
# MasterCleanup object to copy.
def __init__(self, other = None):
# 'cleanups' is a list of cleanups. Each element is either a
# Dummy, for an anonymous cleanup, or a Cleanup, for a cleanup
# which was assigned to a variable.
if other is None:
self.cleanups = []
self.aliases = {}
else:
self.cleanups = other.cleanups[:]
self.aliases = dict(other.aliases)
def compare_vars(self, definition, argument):
if definition == argument:
return True
if argument in self.aliases:
argument = self.aliases[argument]
if definition in self.aliases:
definition = self.aliases[definition]
return definition == argument
def note_assignment(self, lhs, rhs):
log('noting assignment %s = %s' % (lhs, rhs), 4)
self.aliases[lhs] = rhs
# Merge with another MasterCleanup.
# Returns True if this resulted in a change to our state.
def merge(self, other):
# We do explicit iteration like this so we can easily
# update the list after the loop.
counter = -1
found_named = False
for counter in range(len(self.cleanups) - 1, -1, -1):
var = self.cleanups[counter]
log('merge checking %s' % var, 4)
# Only interested in named cleanups.
if isinstance(var, Dummy):
log('=> merge dummy', 5)
continue
# Now see if VAR is found in OTHER.
if other._find_var(var.var) >= 0:
log ('=> merge found', 5)
break
log('=>merge not found', 5)
found_named = True
if found_named and counter < len(self.cleanups) - 1:
log ('merging to %d' % counter, 4)
if counter < 0:
self.cleanups = []
else:
self.cleanups = self.cleanups[0:counter]
return True
# If SELF is empty but OTHER has some cleanups, then consider
# that a change as well.
if len(self.cleanups) == 0 and len(other.cleanups) > 0:
log('merging non-empty other', 4)
self.cleanups = other.cleanups[:]
return True
return False
# Push a new constructor onto our stack. LHS is the
# left-hand-side of the GimpleCall statement. It may be None,
# meaning that this constructor's value wasn't used.
def push(self, location, lhs):
if lhs is None:
obj = Dummy(location)
else:
obj = Cleanup(lhs, location)
log('pushing %s' % lhs, 4)
idx = self._find_var(lhs)
if idx >= 0:
gcc.permerror(location, 'reassigning to known cleanup')
gcc.inform(self.cleanups[idx].location,
'previous assignment is here')
self.cleanups.append(obj)
# A helper for merge and pop that finds BACK_TO in self.cleanups,
# and returns the index, or -1 if not found.
def _find_var(self, back_to):
for i in range(len(self.cleanups) - 1, -1, -1):
if isinstance(self.cleanups[i], Dummy):
continue
if self.compare_vars(self.cleanups[i].var, back_to):
return i
return -1
# Pop constructors until we find one matching BACK_TO.
# This is invoked when we see a do_cleanups call.
def pop(self, location, back_to):
log('pop:', 4)
i = self._find_var(back_to)
if i >= 0:
self.cleanups = self.cleanups[0:i]
else:
gcc.permerror(location, 'destructor call with unknown argument')
# Check whether ARG is the current master cleanup. Return True if
# all is well.
def verify(self, location, arg):
log('verify %s' % arg, 4)
return (len(self.cleanups) > 0
and not isinstance(self.cleanups[0], Dummy)
and self.compare_vars(self.cleanups[0].var, arg))
# Check whether SELF is empty.
def isempty(self):
log('isempty: len = %d' % len(self.cleanups), 4)
return len(self.cleanups) == 0
# Emit informational warnings about the cleanup stack.
def inform(self):
for item in reversed(self.cleanups):
gcc.inform(item.location, 'leaked cleanup')
class CleanupChecker:
def __init__(self, fun):
self.fun = fun
self.seen_edges = set()
self.bad_returns = set()
# This maps BB indices to a list of master cleanups for the
# BB.
self.master_cleanups = {}
# Pick a reasonable location for the basic block BB.
def guess_bb_location(self, bb):
if isinstance(bb.gimple, list):
for stmt in bb.gimple:
if stmt.loc:
return stmt.loc
return self.fun.end
# Compute the master cleanup list for BB.
# Modifies MASTER_CLEANUP in place.
def compute_master(self, bb, bb_from, master_cleanup):
if not isinstance(bb.gimple, list):
return
curloc = self.fun.end
for stmt in bb.gimple:
if stmt.loc:
curloc = stmt.loc
if isinstance(stmt, gcc.GimpleCall) and stmt.fndecl:
if is_constructor(stmt.fndecl):
log('saw constructor %s in bb=%d' % (str(stmt.fndecl), bb.index), 2)
self.cleanup_aware = True
master_cleanup.push(curloc, stmt.lhs)
elif is_destructor(stmt.fndecl):
if str(stmt.fndecl.name) != 'do_cleanups':
self.only_do_cleanups_seen = False
log('saw destructor %s in bb=%d, bb_from=%d, argument=%s'
% (str(stmt.fndecl.name), bb.index, bb_from, str(stmt.args[0])),
2)
master_cleanup.pop(curloc, stmt.args[0])
elif needs_special_treatment(stmt.fndecl):
pass
# gcc.permerror(curloc, 'function needs special treatment')
elif isinstance(stmt, gcc.GimpleAssign):
if isinstance(stmt.lhs, gcc.VarDecl) and isinstance(stmt.rhs[0], gcc.VarDecl):
master_cleanup.note_assignment(stmt.lhs, stmt.rhs[0])
elif isinstance(stmt, gcc.GimpleReturn):
if self.is_constructor:
if not master_cleanup.verify(curloc, stmt.retval):
gcc.permerror(curloc,
'constructor does not return master cleanup')
elif not self.is_special_constructor:
if not master_cleanup.isempty():
if curloc not in self.bad_returns:
gcc.permerror(curloc, 'cleanup stack is not empty at return')
self.bad_returns.add(curloc)
master_cleanup.inform()
# Traverse a basic block, updating the master cleanup information
# and propagating to other blocks.
def traverse_bbs(self, edge, bb, bb_from, entry_master):
log('traverse_bbs %d from %d' % (bb.index, bb_from), 1)
# Propagate the entry MasterCleanup though this block.
master_cleanup = MasterCleanup(entry_master)
self.compute_master(bb, bb_from, master_cleanup)
modified = False
if bb.index in self.master_cleanups:
# Merge the newly-computed MasterCleanup into the one we
# have already computed. If this resulted in a
# significant change, then we need to re-propagate.
modified = self.master_cleanups[bb.index].merge(master_cleanup)
else:
self.master_cleanups[bb.index] = master_cleanup
modified = True
# EDGE is None for the entry BB.
if edge is not None:
# If merging cleanups caused a change, check to see if we
# have a bad loop.
if edge in self.seen_edges:
# This error doesn't really help.
# if modified:
# gcc.permerror(self.guess_bb_location(bb),
# 'invalid cleanup use in loop')
return
self.seen_edges.add(edge)
if not modified:
return
# Now propagate to successor nodes.
for edge in bb.succs:
self.traverse_bbs(edge, edge.dest, bb.index, master_cleanup)
def check_cleanups(self):
if not self.fun.cfg or not self.fun.decl:
return 'ignored'
if is_destructor(self.fun.decl):
return 'destructor'
if needs_special_treatment(self.fun.decl):
return 'special'
self.is_constructor = is_constructor(self.fun.decl)
self.is_special_constructor = not self.is_constructor and str(self.fun.decl.name).find('with_cleanup') > -1
# Yuck.
if str(self.fun.decl.name) == 'gdb_xml_create_parser_and_cleanup_1':
self.is_special_constructor = True
if self.is_special_constructor:
gcc.inform(self.fun.start, 'function %s is a special constructor' % (self.fun.decl.name))
# If we only see do_cleanups calls, and this function is not
# itself a constructor, then we can convert it easily to RAII.
self.only_do_cleanups_seen = not self.is_constructor
# If we ever call a constructor, then we are "cleanup-aware".
self.cleanup_aware = False
entry_bb = self.fun.cfg.entry
master_cleanup = MasterCleanup()
self.traverse_bbs(None, entry_bb, -1, master_cleanup)
if want_raii_info and self.only_do_cleanups_seen and self.cleanup_aware:
gcc.inform(self.fun.decl.location,
'function %s could be converted to RAII' % (self.fun.decl.name))
if self.is_constructor:
return 'constructor'
return 'OK'
class CheckerPass(gcc.GimplePass):
def execute(self, fun):
if fun.decl:
log("Starting " + fun.decl.name)
if show_cfg:
dot = gccutils.cfg_to_dot(fun.cfg, fun.decl.name)
gccutils.invoke_dot(dot, name=fun.decl.name)
checker = CleanupChecker(fun)
what = checker.check_cleanups()
if fun.decl:
log(fun.decl.name + ': ' + what, 2)
ps = CheckerPass(name = 'check-cleanups')
# We need the cfg, but we want a relatively high-level Gimple.
ps.register_after('cfg')