# Derived from nova/network/linux_net.py # # Copyright (c) 2011 X.commerce, a business unit of eBay Inc. # Copyright 2010 United States Government as represented by the # Administrator of the National Aeronautics and Space Administration. # All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); you may # not use this file except in compliance with the License. You may obtain # a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, WITHOUT # WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the # License for the specific language governing permissions and limitations # under the License. # TODO(jaypipes): Replace this entire module with use of the python-iptables # library: https://github.com/ldx/python-iptables import inspect import os import re from oslo_concurrency import lockutils from oslo_concurrency import processutils import six # NOTE(vish): Iptables supports chain names of up to 28 characters, and we # add up to 12 characters to binary_name which is used as a prefix, # so we limit it to 16 characters. # (max_chain_name_length - len('-POSTROUTING') == 16) def get_binary_name(): """Grab the name of the binary we're running in.""" return os.path.basename(inspect.stack()[-1][1])[:16] binary_name = get_binary_name() class IptablesRule(object): """An iptables rule. You shouldn't need to use this class directly, it's only used by IptablesManager. """ def __init__(self, chain, rule, wrap=True, top=False): self.chain = chain self.rule = rule self.wrap = wrap self.top = top def __eq__(self, other): return ((self.chain == other.chain) and (self.rule == other.rule) and (self.top == other.top) and (self.wrap == other.wrap)) def __ne__(self, other): return not self == other def __repr__(self): if self.wrap: chain = '%s-%s' % (binary_name, self.chain) else: chain = self.chain # new rules should have a zero [packet: byte] count return '[0:0] -A %s %s' % (chain, self.rule) class IptablesTable(object): """An iptables table.""" def __init__(self): self.rules = [] self.remove_rules = [] self.chains = set() self.unwrapped_chains = set() self.remove_chains = set() self.dirty = True def has_chain(self, name, wrap=True): if wrap: return name in self.chains else: return name in self.unwrapped_chains def add_chain(self, name, wrap=True): """Adds a named chain to the table. The chain name is wrapped to be unique for the component creating it, so different components of Nova can safely create identically named chains without interfering with one another. At the moment, its wrapped name is -, so if nova-compute creates a chain named 'OUTPUT', it'll actually end up named 'nova-compute-OUTPUT'. """ if wrap: self.chains.add(name) else: self.unwrapped_chains.add(name) self.dirty = True def remove_chain(self, name, wrap=True): """Remove named chain. This removal "cascades". All rule in the chain are removed, as are all rules in other chains that jump to it. If the chain is not found, this is merely logged. """ if wrap: chain_set = self.chains else: chain_set = self.unwrapped_chains if name not in chain_set: return self.dirty = True # non-wrapped chains and rules need to be dealt with specially, # so we keep a list of them to be iterated over in apply() if not wrap: self.remove_chains.add(name) chain_set.remove(name) if not wrap: self.remove_rules += filter(lambda r: r.chain == name, self.rules) self.rules = filter(lambda r: r.chain != name, self.rules) if wrap: jump_snippet = '-j %s-%s' % (binary_name, name) else: jump_snippet = '-j %s' % (name,) if not wrap: self.remove_rules += filter(lambda r: jump_snippet in r.rule, self.rules) self.rules = filter(lambda r: jump_snippet not in r.rule, self.rules) def add_rule(self, chain, rule, wrap=True, top=False): """Add a rule to the table. This is just like what you'd feed to iptables, just without the '-A ' bit at the start. However, if you need to jump to one of your wrapped chains, prepend its name with a '$' which will ensure the wrapping is applied correctly. """ if wrap and chain not in self.chains: raise ValueError(_('Unknown chain: %r') % chain) if '$' in rule: rule = ' '.join(map(self._wrap_target_chain, rule.split(' '))) rule_obj = IptablesRule(chain, rule, wrap, top) if rule_obj not in self.rules: self.rules.append(IptablesRule(chain, rule, wrap, top)) self.dirty = True def _wrap_target_chain(self, s): if s.startswith('$'): return '%s-%s' % (binary_name, s[1:]) return s def remove_rule(self, chain, rule, wrap=True, top=False): """Remove a rule from a chain. Note: The rule must be exactly identical to the one that was added. You cannot switch arguments around like you can with the iptables CLI tool. """ try: self.rules.remove(IptablesRule(chain, rule, wrap, top)) if not wrap: self.remove_rules.append(IptablesRule(chain, rule, wrap, top)) self.dirty = True except ValueError: pass def remove_rules_regex(self, regex): """Remove all rules matching regex.""" if isinstance(regex, six.string_types): regex = re.compile(regex) num_rules = len(self.rules) self.rules = filter(lambda r: not regex.match(str(r)), self.rules) removed = num_rules - len(self.rules) if removed > 0: self.dirty = True return removed def empty_chain(self, chain, wrap=True): """Remove all rules from a chain.""" chained_rules = [rule for rule in self.rules if rule.chain == chain and rule.wrap == wrap] if chained_rules: self.dirty = True for rule in chained_rules: self.rules.remove(rule) class IptablesManager(object): """Wrapper for iptables. See IptablesTable for some usage docs A number of chains are set up to begin with. First, nova-filter-top. It's added at the top of FORWARD and OUTPUT. Its name is not wrapped, so it's shared between the various nova workers. It's intended for rules that need to live at the top of the FORWARD and OUTPUT chains. It's in both the ipv4 and ipv6 set of tables. For ipv4 and ipv6, the built-in INPUT, OUTPUT, and FORWARD filter chains are wrapped, meaning that the "real" INPUT chain has a rule that jumps to the wrapped INPUT chain, etc. Additionally, there's a wrapped chain named "local" which is jumped to from nova-filter-top. For ipv4, the built-in PREROUTING, OUTPUT, and POSTROUTING nat chains are wrapped in the same was as the built-in filter chains. Additionally, there's a snat chain that is applied after the POSTROUTING chain. """ def __init__(self, use_ipv6=False, iptables_top_regex=None, iptables_bottom_regex=None, iptables_drop_action='DROP', forward_bridge_interface=None): self.use_ipv6 = use_ipv6 self.iptables_top_regex = iptables_top_regex self.iptables_bottom_regex = iptables_bottom_regex self.iptables_drop_action = iptables_drop_action self.forward_bridge_interface = forward_bridge_interface or ['all'] self.ipv4 = {'filter': IptablesTable(), 'nat': IptablesTable(), 'mangle': IptablesTable()} self.ipv6 = {'filter': IptablesTable()} self.iptables_apply_deferred = False # Add a nova-filter-top chain. It's intended to be shared # among the various nova components. It sits at the very top # of FORWARD and OUTPUT. for tables in [self.ipv4, self.ipv6]: tables['filter'].add_chain('nova-filter-top', wrap=False) tables['filter'].add_rule('FORWARD', '-j nova-filter-top', wrap=False, top=True) tables['filter'].add_rule('OUTPUT', '-j nova-filter-top', wrap=False, top=True) tables['filter'].add_chain('local') tables['filter'].add_rule('nova-filter-top', '-j $local', wrap=False) # Wrap the built-in chains builtin_chains = {4: {'filter': ['INPUT', 'OUTPUT', 'FORWARD'], 'nat': ['PREROUTING', 'OUTPUT', 'POSTROUTING'], 'mangle': ['POSTROUTING']}, 6: {'filter': ['INPUT', 'OUTPUT', 'FORWARD']}} for ip_version in builtin_chains: if ip_version == 4: tables = self.ipv4 elif ip_version == 6: tables = self.ipv6 for table, chains in six.iteritems(builtin_chains[ip_version]): for chain in chains: tables[table].add_chain(chain) tables[table].add_rule(chain, '-j $%s' % (chain,), wrap=False) # Add a nova-postrouting-bottom chain. It's intended to be shared # among the various nova components. We set it as the last chain # of POSTROUTING chain. self.ipv4['nat'].add_chain('nova-postrouting-bottom', wrap=False) self.ipv4['nat'].add_rule('POSTROUTING', '-j nova-postrouting-bottom', wrap=False) # We add a snat chain to the shared nova-postrouting-bottom chain # so that it's applied last. self.ipv4['nat'].add_chain('snat') self.ipv4['nat'].add_rule('nova-postrouting-bottom', '-j $snat', wrap=False) # And then we add a float-snat chain and jump to first thing in # the snat chain. self.ipv4['nat'].add_chain('float-snat') self.ipv4['nat'].add_rule('snat', '-j $float-snat') def defer_apply_on(self): self.iptables_apply_deferred = True def defer_apply_off(self): self.iptables_apply_deferred = False self.apply() def dirty(self): for table in six.itervalues(self.ipv4): if table.dirty: return True if self.use_ipv6: for table in six.itervalues(self.ipv6): if table.dirty: return True return False def apply(self): if self.iptables_apply_deferred: return if self.dirty(): self._apply() @lockutils.synchronized('nova-iptables', external=True) def _apply(self): """Apply the current in-memory set of iptables rules. This will blow away any rules left over from previous runs of the same component of Nova, and replace them with our current set of rules. This happens atomically, thanks to iptables-restore. """ s = [('iptables', self.ipv4)] if self.use_ipv6: s += [('ip6tables', self.ipv6)] for cmd, tables in s: all_tables, _err = processutils.execute('%s-save' % (cmd,), '-c', attempts=5, run_as_root=True) all_lines = all_tables.split('\n') for table_name, table in six.iteritems(tables): start, end = self._find_table(all_lines, table_name) all_lines[start:end] = self._modify_rules( all_lines[start:end], table, table_name) table.dirty = False processutils.execute('%s-restore' % (cmd,), '-c', process_input='\n'.join(all_lines), attempts=5, run_as_root=True) def _find_table(self, lines, table_name): if len(lines) < 3: # length only <2 when fake iptables return (0, 0) try: start = lines.index('*%s' % table_name) - 1 except ValueError: # Couldn't find table_name return (0, 0) end = lines[start:].index('COMMIT') + start + 2 return (start, end) def _modify_rules(self, current_lines, table, table_name): unwrapped_chains = table.unwrapped_chains chains = sorted(table.chains) remove_chains = table.remove_chains rules = table.rules remove_rules = table.remove_rules if not current_lines: fake_table = ['#Generated by nova', '*' + table_name, 'COMMIT', '#Completed by nova'] current_lines = fake_table # Remove any trace of our rules new_filter = filter(lambda line: binary_name not in line, current_lines) top_rules = [] bottom_rules = [] if self.iptables_top_regex: regex = re.compile(self.iptables_top_regex) temp_filter = filter(lambda line: regex.search(line), new_filter) for rule_str in temp_filter: new_filter = filter(lambda s: s.strip() != rule_str.strip(), new_filter) top_rules = temp_filter if self.iptables_bottom_regex: regex = re.compile(self.iptables_bottom_regex) temp_filter = filter(lambda line: regex.search(line), new_filter) for rule_str in temp_filter: new_filter = filter(lambda s: s.strip() != rule_str.strip(), new_filter) bottom_rules = temp_filter seen_chains = False rules_index = 0 for rules_index, rule in enumerate(new_filter): if not seen_chains: if rule.startswith(':'): seen_chains = True else: if not rule.startswith(':'): break if not seen_chains: rules_index = 2 our_rules = top_rules bot_rules = [] for rule in rules: rule_str = str(rule) if rule.top: # rule.top == True means we want this rule to be at the top. # Further down, we weed out duplicates from the bottom of the # list, so here we remove the dupes ahead of time. # We don't want to remove an entry if it has non-zero # [packet:byte] counts and replace it with [0:0], so let's # go look for a duplicate, and over-ride our table rule if # found. # ignore [packet:byte] counts at beginning of line if rule_str.startswith('['): rule_str = rule_str.split(']', 1)[1] dup_filter = filter(lambda s: rule_str.strip() in s.strip(), new_filter) new_filter = filter(lambda s: rule_str.strip() not in s.strip(), new_filter) # if no duplicates, use original rule if dup_filter: # grab the last entry, if there is one dup = dup_filter[-1] rule_str = str(dup) else: rule_str = str(rule) rule_str.strip() our_rules += [rule_str] else: bot_rules += [rule_str] our_rules += bot_rules new_filter[rules_index:rules_index] = our_rules new_filter[rules_index:rules_index] = [':%s - [0:0]' % (name,) for name in unwrapped_chains] new_filter[rules_index:rules_index] = [':%s-%s - [0:0]' % (binary_name, name,) for name in chains] commit_index = new_filter.index('COMMIT') new_filter[commit_index:commit_index] = bottom_rules seen_lines = set() def _weed_out_duplicates(line): # ignore [packet:byte] counts at beginning of lines if line.startswith('['): line = line.split(']', 1)[1] line = line.strip() if line in seen_lines: return False else: seen_lines.add(line) return True def _weed_out_removes(line): # We need to find exact matches here if line.startswith(':'): # it's a chain, for example, ":nova-billing - [0:0]" # strip off everything except the chain name line = line.split(':')[1] line = line.split('- [')[0] line = line.strip() for chain in remove_chains: if chain == line: remove_chains.remove(chain) return False elif line.startswith('['): # it's a rule # ignore [packet:byte] counts at beginning of lines line = line.split(']', 1)[1] line = line.strip() for rule in remove_rules: # ignore [packet:byte] counts at beginning of rules rule_str = str(rule) rule_str = rule_str.split(' ', 1)[1] rule_str = rule_str.strip() if rule_str == line: remove_rules.remove(rule) return False # Leave it alone return True # We filter duplicates, letting the *last* occurrence take # precedence. We also filter out anything in the "remove" # lists. new_filter.reverse() new_filter = filter(_weed_out_duplicates, new_filter) new_filter = filter(_weed_out_removes, new_filter) new_filter.reverse() # flush lists, just in case we didn't find something remove_chains.clear() for rule in remove_rules: remove_rules.remove(rule) return new_filter def get_gateway_rules(self, bridge): interfaces = self.forward_bridge_interface if 'all' in interfaces: return [('FORWARD', '-i %s -j ACCEPT' % bridge), ('FORWARD', '-o %s -j ACCEPT' % bridge)] rules = [] for iface in self.forward_bridge_interface: if iface: rules.append(('FORWARD', '-i %s -o %s -j ACCEPT' % (bridge, iface))) rules.append(('FORWARD', '-i %s -o %s -j ACCEPT' % (iface, bridge))) rules.append(('FORWARD', '-i %s -o %s -j ACCEPT' % (bridge, bridge))) rules.append(('FORWARD', '-i %s -j %s' % (bridge, self.iptables_drop_action))) rules.append(('FORWARD', '-o %s -j %s' % (bridge, self.iptables_drop_action))) return rules