# Copyright 2012 Locaweb. # 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. # # based on # https://github.com/openstack/nova/blob/master/nova/network/linux_net.py """Implements iptables rules using linux utilities.""" import collections import contextlib import difflib import os import re import sys from oslo_concurrency import lockutils from oslo_config import cfg from oslo_log import log as logging from oslo_utils import excutils import six from neutron._i18n import _, _LE, _LW from neutron.agent.linux import iptables_comments as ic from neutron.agent.linux import utils as linux_utils from neutron.common import exceptions as n_exc from neutron.common import utils from neutron.conf.agent import common as config LOG = logging.getLogger(__name__) config.register_iptables_opts(cfg.CONF) # 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(sys.argv[0])[:16].replace(' ', '_') binary_name = get_binary_name() # A length of a chain name must be less than or equal to 11 characters. # - ( + '-') = 28-(16+1) = 11 MAX_CHAIN_LEN_WRAP = 11 MAX_CHAIN_LEN_NOWRAP = 28 # Number of iptables rules to print before and after a rule that causes a # a failure during iptables-restore IPTABLES_ERROR_LINES_OF_CONTEXT = 5 def comment_rule(rule, comment): if not cfg.CONF.AGENT.comment_iptables_rules or not comment: return rule # iptables-save outputs the comment before the jump so we need to match # that order so _find_last_entry works comment = '-m comment --comment "%s"' % comment if rule.startswith('-j'): # this is a jump only rule so we just put the comment first return '%s %s' % (comment, rule) try: jpos = rule.index(' -j ') return ' '.join((rule[:jpos], comment, rule[jpos + 1:])) except ValueError: return '%s %s' % (rule, comment) def get_chain_name(chain_name, wrap=True): if wrap: return chain_name[:MAX_CHAIN_LEN_WRAP] else: return chain_name[:MAX_CHAIN_LEN_NOWRAP] 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, binary_name=binary_name, tag=None, comment=None): self.chain = get_chain_name(chain, wrap) self.rule = rule self.wrap = wrap self.top = top self.wrap_name = binary_name[:16] self.tag = tag self.comment = comment 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 __str__(self): if self.wrap: chain = '%s-%s' % (self.wrap_name, self.chain) else: chain = self.chain rule = '-A %s %s' % (chain, self.rule) # If self.rule is '' the above will cause a trailing space, which # could cause us to not match on save/restore, so strip it now. return comment_rule(rule.strip(), self.comment) class IptablesTable(object): """An iptables table.""" def __init__(self, binary_name=binary_name): self.rules = [] self.remove_rules = [] self.chains = set() self.unwrapped_chains = set() self.remove_chains = set() self.wrap_name = binary_name[:16] 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 neutron-openvswitch-agent creates a chain named 'OUTPUT', it'll actually end up being named 'neutron-openvswi-OUTPUT'. """ name = get_chain_name(name, wrap) if wrap: self.chains.add(name) else: self.unwrapped_chains.add(name) def _select_chain_set(self, wrap): if wrap: return self.chains else: return self.unwrapped_chains 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. """ name = get_chain_name(name, wrap) chain_set = self._select_chain_set(wrap) if name not in chain_set: LOG.debug('Attempted to remove chain %s which does not exist', name) return chain_set.remove(name) if not wrap: # non-wrapped chains and rules need to be dealt with specially, # so we keep a list of them to be iterated over in apply() self.remove_chains.add(name) # Add rules to remove that have a matching chain name or # a matching jump chain jump_snippet = '-j %s' % name self.remove_rules += [str(r) for r in self.rules if r.chain == name or jump_snippet in r.rule] else: jump_snippet = '-j %s-%s' % (self.wrap_name, name) # Remove rules from list that have a matching chain name or # a matching jump chain self.rules = [r for r in self.rules if r.chain != name and jump_snippet not in r.rule] def add_rule(self, chain, rule, wrap=True, top=False, tag=None, comment=None): """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 '$' which will ensure the wrapping is applied correctly. """ chain = get_chain_name(chain, wrap) if wrap and chain not in self.chains: raise LookupError(_('Unknown chain: %r') % chain) if '$' in rule: rule = ' '.join( self._wrap_target_chain(e, wrap) for e in rule.split(' ')) self.rules.append(IptablesRule(chain, rule, wrap, top, self.wrap_name, tag, comment)) def _wrap_target_chain(self, s, wrap): if s.startswith('$'): s = ('%s-%s' % (self.wrap_name, get_chain_name(s[1:], wrap))) return s def remove_rule(self, chain, rule, wrap=True, top=False, comment=None): """Remove a rule from a chain. Note: The rule must be exactly identical to the one that was added. You cannot switch arguments around like you can with the iptables CLI tool. """ chain = get_chain_name(chain, wrap) try: if '$' in rule: rule = ' '.join( self._wrap_target_chain(e, wrap) for e in rule.split(' ')) self.rules.remove(IptablesRule(chain, rule, wrap, top, self.wrap_name, comment=comment)) if not wrap: self.remove_rules.append(str(IptablesRule(chain, rule, wrap, top, self.wrap_name, comment=comment))) except ValueError: LOG.warning(_LW('Tried to remove rule that was not there:' ' %(chain)r %(rule)r %(wrap)r %(top)r'), {'chain': chain, 'rule': rule, 'top': top, 'wrap': wrap}) def _get_chain_rules(self, chain, wrap): chain = get_chain_name(chain, wrap) return [rule for rule in self.rules if rule.chain == chain and rule.wrap == wrap] def empty_chain(self, chain, wrap=True): """Remove all rules from a chain.""" chained_rules = self._get_chain_rules(chain, wrap) for rule in chained_rules: self.rules.remove(rule) def clear_rules_by_tag(self, tag): if not tag: return rules = [rule for rule in self.rules if rule.tag == tag] for rule in 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, neutron-filter-top. It's added at the top of FORWARD and OUTPUT. Its name is not wrapped, so it's shared between the various neutron 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 neutron-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, _execute=None, state_less=False, use_ipv6=False, namespace=None, binary_name=binary_name): if _execute: self.execute = _execute else: self.execute = linux_utils.execute self.use_ipv6 = use_ipv6 self.namespace = namespace self.iptables_apply_deferred = False self.wrap_name = binary_name[:16] self.ipv4 = {'filter': IptablesTable(binary_name=self.wrap_name)} self.ipv6 = {'filter': IptablesTable(binary_name=self.wrap_name)} # Add a neutron-filter-top chain. It's intended to be shared # among the various neutron components. It sits at the very top # of FORWARD and OUTPUT. for tables in [self.ipv4, self.ipv6]: tables['filter'].add_chain('neutron-filter-top', wrap=False) tables['filter'].add_rule('FORWARD', '-j neutron-filter-top', wrap=False, top=True) tables['filter'].add_rule('OUTPUT', '-j neutron-filter-top', wrap=False, top=True) tables['filter'].add_chain('local') tables['filter'].add_rule('neutron-filter-top', '-j $local', wrap=False) # Wrap the built-in chains builtin_chains = {4: {'filter': ['INPUT', 'OUTPUT', 'FORWARD']}, 6: {'filter': ['INPUT', 'OUTPUT', 'FORWARD']}} if not state_less: self.ipv4.update( {'mangle': IptablesTable(binary_name=self.wrap_name)}) builtin_chains[4].update( {'mangle': ['PREROUTING', 'INPUT', 'FORWARD', 'OUTPUT', 'POSTROUTING']}) self.ipv6.update( {'mangle': IptablesTable(binary_name=self.wrap_name)}) builtin_chains[6].update( {'mangle': ['PREROUTING', 'INPUT', 'FORWARD', 'OUTPUT', 'POSTROUTING']}) self.ipv4.update( {'nat': IptablesTable(binary_name=self.wrap_name)}) builtin_chains[4].update({'nat': ['PREROUTING', 'OUTPUT', 'POSTROUTING']}) self.ipv4.update({'raw': IptablesTable(binary_name=self.wrap_name)}) builtin_chains[4].update({'raw': ['PREROUTING', 'OUTPUT']}) self.ipv6.update({'raw': IptablesTable(binary_name=self.wrap_name)}) builtin_chains[6].update({'raw': ['PREROUTING', 'OUTPUT']}) 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) if not state_less: # Add a neutron-postrouting-bottom chain. It's intended to be # shared among the various neutron components. We set it as the # last chain of POSTROUTING chain. self.ipv4['nat'].add_chain('neutron-postrouting-bottom', wrap=False) self.ipv4['nat'].add_rule('POSTROUTING', '-j neutron-postrouting-bottom', wrap=False) # We add a snat chain to the shared neutron-postrouting-bottom # chain so that it's applied last. self.ipv4['nat'].add_chain('snat') self.ipv4['nat'].add_rule('neutron-postrouting-bottom', '-j $snat', wrap=False, comment=ic.SNAT_OUT) # 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') # Add a mark chain to mangle PREROUTING chain. It is used to # identify ingress packets from a certain interface. self.ipv4['mangle'].add_chain('mark') self.ipv4['mangle'].add_rule('PREROUTING', '-j $mark') def get_tables(self, ip_version): return {4: self.ipv4, 6: self.ipv6}[ip_version] def get_chain(self, table, chain, ip_version=4, wrap=True): try: requested_table = self.get_tables(ip_version)[table] except KeyError: return [] return requested_table._get_chain_rules(chain, wrap) def is_chain_empty(self, table, chain, ip_version=4, wrap=True): return not self.get_chain(table, chain, ip_version, wrap) @contextlib.contextmanager def defer_apply(self): """Defer apply context.""" self.defer_apply_on() try: yield finally: try: self.defer_apply_off() except n_exc.IpTablesApplyException: # already in the format we want, just reraise raise except Exception: msg = _('Failure applying iptables rules') LOG.exception(msg) raise n_exc.IpTablesApplyException(msg) def defer_apply_on(self): self.iptables_apply_deferred = True def defer_apply_off(self): self.iptables_apply_deferred = False self._apply() def apply(self): if self.iptables_apply_deferred: return return self._apply() def _apply(self): lock_name = 'iptables' if self.namespace: lock_name += '-' + self.namespace with lockutils.lock(lock_name, utils.SYNCHRONIZED_PREFIX, True): first = self._apply_synchronized() if not cfg.CONF.AGENT.debug_iptables_rules: return first second = self._apply_synchronized() if second: msg = (_("IPTables Rules did not converge. Diff: %s") % '\n'.join(second)) LOG.error(msg) raise n_exc.IpTablesApplyException(msg) return first def get_rules_for_table(self, table): """Runs iptables-save on a table and returns the results.""" args = ['iptables-save', '-t', table] if self.namespace: args = ['ip', 'netns', 'exec', self.namespace] + args return self.execute(args, run_as_root=True).split('\n') def _apply_synchronized(self): """Apply the current in-memory set of iptables rules. This will create a diff between the rules from the previous runs and replace them with the current set of rules. This happens atomically, thanks to iptables-restore. Returns a list of the changes that were sent to iptables-save. """ s = [('iptables', self.ipv4)] if self.use_ipv6: s += [('ip6tables', self.ipv6)] all_commands = [] # variable to keep track all commands for return val for cmd, tables in s: args = ['%s-save' % (cmd,)] if self.namespace: args = ['ip', 'netns', 'exec', self.namespace] + args save_output = self.execute(args, run_as_root=True) all_lines = save_output.split('\n') commands = [] # Traverse tables in sorted order for predictable dump output for table_name in sorted(tables): table = tables[table_name] # isolate the lines of the table we are modifying start, end = self._find_table(all_lines, table_name) old_rules = all_lines[start:end] # generate the new table state we want new_rules = self._modify_rules(old_rules, table, table_name) # generate the iptables commands to get between the old state # and the new state changes = _generate_path_between_rules(old_rules, new_rules) if changes: # if there are changes to the table, we put on the header # and footer that iptables-save needs commands += (['# Generated by iptables_manager'] + ['*%s' % table_name] + changes + ['COMMIT', '# Completed by iptables_manager']) if not commands: continue all_commands += commands args = ['%s-restore' % (cmd,), '-n'] if self.namespace: args = ['ip', 'netns', 'exec', self.namespace] + args try: # always end with a new line commands.append('') self.execute(args, process_input='\n'.join(commands), run_as_root=True) except RuntimeError as r_error: with excutils.save_and_reraise_exception(): try: line_no = int(re.search( 'iptables-restore: line ([0-9]+?) failed', str(r_error)).group(1)) context = IPTABLES_ERROR_LINES_OF_CONTEXT log_start = max(0, line_no - context) log_end = line_no + context except AttributeError: # line error wasn't found, print all lines instead log_start = 0 log_end = len(commands) log_lines = ('%7d. %s' % (idx, l) for idx, l in enumerate( commands[log_start:log_end], log_start + 1) ) LOG.error(_LE("IPTablesManager.apply failed to apply the " "following set of iptables rules:\n%s"), '\n'.join(log_lines)) LOG.debug("IPTablesManager.apply completed with success. %d iptables " "commands were issued", len(all_commands)) return all_commands 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) except ValueError: # Couldn't find table_name LOG.debug('Unable to find table %s', table_name) return (0, 0) end = lines[start:].index('COMMIT') + start + 1 return (start, end) def _find_rules_index(self, lines): seen_chains = False rules_index = 0 for rules_index, rule in enumerate(lines): if not seen_chains: if rule.startswith(':'): seen_chains = True else: if not rule.startswith(':'): break if not seen_chains: rules_index = 2 return rules_index def _modify_rules(self, current_lines, table, table_name): # Chains are stored as sets to avoid duplicates. # Sort the output chains here to make their order predictable. unwrapped_chains = sorted(table.unwrapped_chains) chains = sorted(table.chains) rules = set(map(str, table.rules)) # we don't want to change any rules that don't belong to us so we start # the new_filter with these rules # there are some rules that belong to us but they don't have the wrap # name. we want to add them in the right location in case our new rules # changed the order # (e.g. '-A FORWARD -j neutron-filter-top') new_filter = [line.strip() for line in current_lines if self.wrap_name not in line and line.strip() not in rules] # generate our list of chain names our_chains = [':%s-%s' % (self.wrap_name, name) for name in chains] # the unwrapped chains (e.g. neutron-filter-top) may already exist in # the new_filter since they aren't marked by the wrap_name so we only # want to add them if they arent' already there our_chains += [':%s' % name for name in unwrapped_chains if not any(':%s' % name in s for s in new_filter)] our_top_rules = [] our_bottom_rules = [] for rule in table.rules: rule_str = str(rule) if rule.top: # rule.top == True means we want this rule to be at the top. our_top_rules += [rule_str] else: our_bottom_rules += [rule_str] our_chains_and_rules = our_chains + our_top_rules + our_bottom_rules # locate the position immediately after the existing chains to insert # our chains and rules rules_index = self._find_rules_index(new_filter) new_filter[rules_index:rules_index] = our_chains_and_rules def _weed_out_removes(line): # remove any rules or chains from the filter that were slated # for removal if line.startswith(':'): chain = line[1:] if chain in table.remove_chains: table.remove_chains.remove(chain) return False else: if line in table.remove_rules: table.remove_rules.remove(line) return False # Leave it alone return True seen_lines = set() # TODO(kevinbenton): remove this function and the next one. They are # just oversized brooms to sweep bugs under the rug!!! We generate the # rules and we shouldn't be generating duplicates. def _weed_out_duplicates(line): if line in seen_lines: thing = 'chain' if line.startswith(':') else 'rule' LOG.warning(_LW("Duplicate iptables %(thing)s detected. This " "may indicate a bug in the iptables " "%(thing)s generation code. Line: %(line)s"), {'thing': thing, 'line': line}) return False seen_lines.add(line) # Leave it alone return True new_filter.reverse() new_filter = [line for line in new_filter if _weed_out_duplicates(line) and _weed_out_removes(line)] new_filter.reverse() # flush lists, just in case a rule or chain marked for removal # was already gone. (chains is a set, rules is a list) table.remove_chains.clear() table.remove_rules = [] return new_filter def _get_traffic_counters_cmd_tables(self, chain, wrap=True): name = get_chain_name(chain, wrap) cmd_tables = [('iptables', key) for key, table in self.ipv4.items() if name in table._select_chain_set(wrap)] if self.use_ipv6: cmd_tables += [('ip6tables', key) for key, table in self.ipv6.items() if name in table._select_chain_set(wrap)] return cmd_tables def get_traffic_counters(self, chain, wrap=True, zero=False): """Return the sum of the traffic counters of all rules of a chain.""" cmd_tables = self._get_traffic_counters_cmd_tables(chain, wrap) if not cmd_tables: LOG.warning(_LW('Attempted to get traffic counters of chain %s ' 'which does not exist'), chain) return name = get_chain_name(chain, wrap) acc = {'pkts': 0, 'bytes': 0} for cmd, table in cmd_tables: args = [cmd, '-t', table, '-L', name, '-n', '-v', '-x'] if zero: args.append('-Z') if self.namespace: args = ['ip', 'netns', 'exec', self.namespace] + args current_table = self.execute(args, run_as_root=True) current_lines = current_table.split('\n') for line in current_lines[2:]: if not line: break data = line.split() if (len(data) < 2 or not data[0].isdigit() or not data[1].isdigit()): break acc['pkts'] += int(data[0]) acc['bytes'] += int(data[1]) return acc def _generate_path_between_rules(old_rules, new_rules): """Generates iptables commands to get from old_rules to new_rules. This function diffs the two rule sets and then calculates the iptables commands necessary to get from the old rules to the new rules using insert and delete commands. """ old_by_chain = _get_rules_by_chain(old_rules) new_by_chain = _get_rules_by_chain(new_rules) old_chains, new_chains = set(old_by_chain.keys()), set(new_by_chain.keys()) # all referenced chains should be declared at the top before rules. # NOTE(kevinbenton): sorting and grouping chains is for determinism in # tests. iptables doesn't care about the order here statements = [':%s - [0:0]' % c for c in sorted(new_chains - old_chains)] sg_chains = [] other_chains = [] for chain in sorted(old_chains | new_chains): if '-sg-' in chain: sg_chains.append(chain) else: other_chains.append(chain) for chain in other_chains + sg_chains: statements += _generate_chain_diff_iptables_commands( chain, old_by_chain[chain], new_by_chain[chain]) # unreferenced chains get the axe for chain in sorted(old_chains - new_chains): statements += ['-X %s' % chain] return statements def _get_rules_by_chain(rules): by_chain = collections.defaultdict(list) for line in rules: if line.startswith(':'): chain = line[1:].split(' ', 1)[0] # even though this is a default dict, we need to manually add # chains to ensure that ones without rules are included because # they might be a jump reference if chain not in by_chain: by_chain[chain] = [] elif line.startswith('-A'): chain = line[3:].split(' ', 1)[0] by_chain[chain].append(line) return by_chain def _generate_chain_diff_iptables_commands(chain, old_chain_rules, new_chain_rules): # keep track of the old index because we have to insert rules # in the right position old_index = 1 statements = [] for line in difflib.ndiff(old_chain_rules, new_chain_rules): if line.startswith('?'): # skip ? because that's a guide string for intraline differences continue elif line.startswith('-'): # line deleted statements.append('-D %s %d' % (chain, old_index)) # since we are removing a line from the old rules, we # backup the index by 1 old_index -= 1 elif line.startswith('+'): # line added # strip the chain name since we have to add it before the index rule = line[5:].split(' ', 1)[-1] # IptablesRule does not add trailing spaces for rules, so we # have to detect that here by making sure this chain isn't # referencing itself if rule == chain: rule = '' # rule inserted at this position statements.append('-I %s %d %s' % (chain, old_index, rule)) old_index += 1 return statements