// // Copyright (C) 2012 The Android Open Source Project // // 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. // #include "shill/routing_table.h" #include #include #include #include #include #include // NOLINT - must be included after netinet/ether.h #include #include #include #include #include #include #include #include #include #include #include #include #include "shill/ipconfig.h" #include "shill/logging.h" #include "shill/net/byte_string.h" #include "shill/net/rtnl_handler.h" #include "shill/net/rtnl_listener.h" #include "shill/net/rtnl_message.h" #include "shill/routing_table_entry.h" using base::Bind; using base::FilePath; using base::Unretained; using std::deque; using std::string; using std::vector; namespace shill { namespace Logging { static auto kModuleLogScope = ScopeLogger::kRoute; static string ObjectID(RoutingTable* r) { return "(routing_table)"; } } namespace { base::LazyInstance g_routing_table = LAZY_INSTANCE_INITIALIZER; } // namespace // static const char RoutingTable::kRouteFlushPath4[] = "/proc/sys/net/ipv4/route/flush"; // static const char RoutingTable::kRouteFlushPath6[] = "/proc/sys/net/ipv6/route/flush"; RoutingTable::RoutingTable() : route_callback_(Bind(&RoutingTable::RouteMsgHandler, Unretained(this))), rtnl_handler_(RTNLHandler::GetInstance()) { SLOG(this, 2) << __func__; } RoutingTable::~RoutingTable() {} RoutingTable* RoutingTable::GetInstance() { return g_routing_table.Pointer(); } void RoutingTable::Start() { SLOG(this, 2) << __func__; route_listener_.reset( new RTNLListener(RTNLHandler::kRequestRoute, route_callback_)); rtnl_handler_->RequestDump(RTNLHandler::kRequestRoute); } void RoutingTable::Stop() { SLOG(this, 2) << __func__; route_listener_.reset(); } bool RoutingTable::AddRoute(int interface_index, const RoutingTableEntry& entry) { SLOG(this, 2) << __func__ << ": " << "destination " << entry.dst.ToString() << " index " << interface_index << " gateway " << entry.gateway.ToString() << " metric " << entry.metric; CHECK(!entry.from_rtnl); if (!ApplyRoute(interface_index, entry, RTNLMessage::kModeAdd, NLM_F_CREATE | NLM_F_EXCL)) { return false; } tables_[interface_index].push_back(entry); return true; } bool RoutingTable::GetDefaultRoute(int interface_index, IPAddress::Family family, RoutingTableEntry* entry) { RoutingTableEntry* found_entry; bool ret = GetDefaultRouteInternal(interface_index, family, &found_entry); if (ret) { *entry = *found_entry; } return ret; } bool RoutingTable::GetDefaultRouteInternal(int interface_index, IPAddress::Family family, RoutingTableEntry** entry) { SLOG(this, 2) << __func__ << " index " << interface_index << " family " << IPAddress::GetAddressFamilyName(family); Tables::iterator table = tables_.find(interface_index); if (table == tables_.end()) { SLOG(this, 2) << __func__ << " no table"; return false; } for (auto& nent : table->second) { if (nent.dst.IsDefault() && nent.dst.family() == family) { *entry = &nent; SLOG(this, 2) << __func__ << ": found" << " gateway " << nent.gateway.ToString() << " metric " << nent.metric; return true; } } SLOG(this, 2) << __func__ << " no route"; return false; } bool RoutingTable::SetDefaultRoute(int interface_index, const IPAddress& gateway_address, uint32_t metric, uint8_t table_id) { SLOG(this, 2) << __func__ << " index " << interface_index << " metric " << metric; RoutingTableEntry* old_entry; if (GetDefaultRouteInternal(interface_index, gateway_address.family(), &old_entry)) { if (old_entry->gateway.Equals(gateway_address)) { if (old_entry->metric != metric) { ReplaceMetric(interface_index, old_entry, metric); } return true; } else { // TODO(quiche): Update internal state as well? ApplyRoute(interface_index, *old_entry, RTNLMessage::kModeDelete, 0); } } IPAddress default_address(gateway_address.family()); default_address.SetAddressToDefault(); return AddRoute(interface_index, RoutingTableEntry(default_address, default_address, gateway_address, metric, RT_SCOPE_UNIVERSE, false, table_id, RoutingTableEntry::kDefaultTag)); } bool RoutingTable::ConfigureRoutes(int interface_index, const IPConfigRefPtr& ipconfig, uint32_t metric, uint8_t table_id) { bool ret = true; IPAddress::Family address_family = ipconfig->properties().address_family; const vector& routes = ipconfig->properties().routes; for (const auto& route : routes) { SLOG(this, 3) << "Installing route:" << " Destination: " << route.host << " Netmask: " << route.netmask << " Gateway: " << route.gateway; IPAddress destination_address(address_family); IPAddress source_address(address_family); // Left as default. IPAddress gateway_address(address_family); if (!destination_address.SetAddressFromString(route.host)) { LOG(ERROR) << "Failed to parse host " << route.host; ret = false; continue; } if (!gateway_address.SetAddressFromString(route.gateway)) { LOG(ERROR) << "Failed to parse gateway " << route.gateway; ret = false; continue; } destination_address.set_prefix( IPAddress::GetPrefixLengthFromMask(address_family, route.netmask)); if (!AddRoute(interface_index, RoutingTableEntry(destination_address, source_address, gateway_address, metric, RT_SCOPE_UNIVERSE, false, table_id, RoutingTableEntry::kDefaultTag))) { ret = false; } } return ret; } void RoutingTable::FlushRoutes(int interface_index) { SLOG(this, 2) << __func__; auto table = tables_.find(interface_index); if (table == tables_.end()) { return; } for (const auto& nent : table->second) { ApplyRoute(interface_index, nent, RTNLMessage::kModeDelete, 0); } table->second.clear(); } void RoutingTable::FlushRoutesWithTag(int tag) { SLOG(this, 2) << __func__; for (auto& table : tables_) { for (auto nent = table.second.begin(); nent != table.second.end();) { if (nent->tag == tag) { ApplyRoute(table.first, *nent, RTNLMessage::kModeDelete, 0); nent = table.second.erase(nent); } else { ++nent; } } } } void RoutingTable::ResetTable(int interface_index) { tables_.erase(interface_index); } void RoutingTable::SetDefaultMetric(int interface_index, uint32_t metric) { SLOG(this, 2) << __func__ << " index " << interface_index << " metric " << metric; RoutingTableEntry* entry; if (GetDefaultRouteInternal( interface_index, IPAddress::kFamilyIPv4, &entry) && entry->metric != metric) { ReplaceMetric(interface_index, entry, metric); } if (GetDefaultRouteInternal( interface_index, IPAddress::kFamilyIPv6, &entry) && entry->metric != metric) { ReplaceMetric(interface_index, entry, metric); } } // static bool RoutingTable::ParseRoutingTableMessage(const RTNLMessage& message, int* interface_index, RoutingTableEntry* entry) { if (message.type() != RTNLMessage::kTypeRoute || message.family() == IPAddress::kFamilyUnknown || !message.HasAttribute(RTA_OIF)) { return false; } const RTNLMessage::RouteStatus& route_status = message.route_status(); if (route_status.type != RTN_UNICAST) { return false; } uint32_t interface_index_u32 = 0; if (!message.GetAttribute(RTA_OIF).ConvertToCPUUInt32(&interface_index_u32)) { return false; } *interface_index = interface_index_u32; uint32_t metric = 0; if (message.HasAttribute(RTA_PRIORITY)) { message.GetAttribute(RTA_PRIORITY).ConvertToCPUUInt32(&metric); } IPAddress default_addr(message.family()); default_addr.SetAddressToDefault(); ByteString dst_bytes(default_addr.address()); if (message.HasAttribute(RTA_DST)) { dst_bytes = message.GetAttribute(RTA_DST); } ByteString src_bytes(default_addr.address()); if (message.HasAttribute(RTA_SRC)) { src_bytes = message.GetAttribute(RTA_SRC); } ByteString gateway_bytes(default_addr.address()); if (message.HasAttribute(RTA_GATEWAY)) { gateway_bytes = message.GetAttribute(RTA_GATEWAY); } entry->dst = IPAddress(message.family(), dst_bytes, route_status.dst_prefix); entry->src = IPAddress(message.family(), src_bytes, route_status.src_prefix); entry->gateway = IPAddress(message.family(), gateway_bytes); entry->metric = metric; entry->scope = route_status.scope; entry->from_rtnl = true; entry->table = route_status.table; return true; } void RoutingTable::RouteMsgHandler(const RTNLMessage& message) { int interface_index; RoutingTableEntry entry; if (!ParseRoutingTableMessage(message, &interface_index, &entry)) { return; } if (!route_queries_.empty() && message.route_status().protocol == RTPROT_UNSPEC) { SLOG(this, 3) << __func__ << ": Message seq: " << message.seq() << " mode " << message.mode() << ", next query seq: " << route_queries_.front().sequence; // Purge queries that have expired (sequence number of this message is // greater than that of the head of the route query sequence). Do the // math in a way that's roll-over independent. while (route_queries_.front().sequence - message.seq() > kuint32max / 2) { LOG(ERROR) << __func__ << ": Purging un-replied route request sequence " << route_queries_.front().sequence << " (< " << message.seq() << ")"; route_queries_.pop_front(); if (route_queries_.empty()) return; } const Query& query = route_queries_.front(); if (query.sequence == message.seq()) { RoutingTableEntry add_entry(entry); add_entry.from_rtnl = false; add_entry.tag = query.tag; add_entry.table = query.table_id; bool added = true; if (add_entry.gateway.IsDefault()) { SLOG(this, 2) << __func__ << ": Ignoring route result with no gateway " << "since we don't need to plumb these."; } else { SLOG(this, 2) << __func__ << ": Adding host route to " << add_entry.dst.ToString(); added = AddRoute(interface_index, add_entry); } if (added && !query.callback.is_null()) { SLOG(this, 2) << "Running query callback."; query.callback.Run(interface_index, add_entry); } route_queries_.pop_front(); } return; } else if (message.route_status().protocol != RTPROT_BOOT) { // Responses to route queries come back with a protocol of // RTPROT_UNSPEC. Otherwise, normal route updates that we are // interested in come with a protocol of RTPROT_BOOT. return; } TableEntryVector& table = tables_[interface_index]; for (auto nent = table.begin(); nent != table.end(); ++nent) { if (nent->dst.Equals(entry.dst) && nent->src.Equals(entry.src) && nent->gateway.Equals(entry.gateway) && nent->scope == entry.scope) { if (message.mode() == RTNLMessage::kModeDelete && nent->metric == entry.metric) { table.erase(nent); } else if (message.mode() == RTNLMessage::kModeAdd) { nent->from_rtnl = true; nent->metric = entry.metric; } return; } } if (message.mode() == RTNLMessage::kModeAdd) { SLOG(this, 2) << __func__ << " adding" << " destination " << entry.dst.ToString() << " index " << interface_index << " gateway " << entry.gateway.ToString() << " metric " << entry.metric; table.push_back(entry); } } bool RoutingTable::ApplyRoute(uint32_t interface_index, const RoutingTableEntry& entry, RTNLMessage::Mode mode, unsigned int flags) { SLOG(this, 2) << base::StringPrintf( "%s: dst %s/%d src %s/%d index %d mode %d flags 0x%x", __func__, entry.dst.ToString().c_str(), entry.dst.prefix(), entry.src.ToString().c_str(), entry.src.prefix(), interface_index, mode, flags); RTNLMessage message( RTNLMessage::kTypeRoute, mode, NLM_F_REQUEST | flags, 0, 0, 0, entry.dst.family()); message.set_route_status(RTNLMessage::RouteStatus( entry.dst.prefix(), entry.src.prefix(), entry.table, RTPROT_BOOT, entry.scope, RTN_UNICAST, 0)); message.SetAttribute(RTA_DST, entry.dst.address()); if (!entry.src.IsDefault()) { message.SetAttribute(RTA_SRC, entry.src.address()); } if (!entry.gateway.IsDefault()) { message.SetAttribute(RTA_GATEWAY, entry.gateway.address()); } message.SetAttribute(RTA_PRIORITY, ByteString::CreateFromCPUUInt32(entry.metric)); message.SetAttribute(RTA_OIF, ByteString::CreateFromCPUUInt32(interface_index)); return rtnl_handler_->SendMessage(&message); } // Somewhat surprisingly, the kernel allows you to create multiple routes // to the same destination through the same interface with different metrics. // Therefore, to change the metric on a route, we can't just use the // NLM_F_REPLACE flag by itself. We have to explicitly remove the old route. // We do so after creating the route at a new metric so there is no traffic // disruption to existing network streams. void RoutingTable::ReplaceMetric(uint32_t interface_index, RoutingTableEntry* entry, uint32_t metric) { SLOG(this, 2) << __func__ << " index " << interface_index << " metric " << metric; RoutingTableEntry new_entry = *entry; new_entry.metric = metric; // First create the route at the new metric. ApplyRoute(interface_index, new_entry, RTNLMessage::kModeAdd, NLM_F_CREATE | NLM_F_REPLACE); // Then delete the route at the old metric. ApplyRoute(interface_index, *entry, RTNLMessage::kModeDelete, 0); // Now, update our routing table (via |*entry|) from |new_entry|. *entry = new_entry; } bool RoutingTable::FlushCache() { static const char* kPaths[2] = { kRouteFlushPath4, kRouteFlushPath6 }; bool ret = true; SLOG(this, 2) << __func__; for (size_t i = 0; i < arraysize(kPaths); ++i) { if (base::WriteFile(FilePath(kPaths[i]), "-1", 2) != 2) { LOG(ERROR) << base::StringPrintf("Cannot write to route flush file %s", kPaths[i]); ret = false; } } return ret; } bool RoutingTable::RequestRouteToHost(const IPAddress& address, int interface_index, int tag, const Query::Callback& callback, uint8_t table_id) { // Make sure we don't get a cached response that is no longer valid. FlushCache(); RTNLMessage message( RTNLMessage::kTypeRoute, RTNLMessage::kModeQuery, NLM_F_REQUEST, 0, 0, interface_index, address.family()); RTNLMessage::RouteStatus status; status.dst_prefix = address.prefix(); message.set_route_status(status); message.SetAttribute(RTA_DST, address.address()); if (interface_index != -1) { message.SetAttribute(RTA_OIF, ByteString::CreateFromCPUUInt32(interface_index)); } if (!rtnl_handler_->SendMessage(&message)) { return false; } // Save the sequence number of the request so we can create a route for // this host when we get a reply. route_queries_.push_back(Query(message.seq(), tag, callback, table_id)); return true; } bool RoutingTable::CreateBlackholeRoute(int interface_index, IPAddress::Family family, uint32_t metric, uint8_t table_id) { SLOG(this, 2) << base::StringPrintf( "%s: index %d family %s metric %d", __func__, interface_index, IPAddress::GetAddressFamilyName(family).c_str(), metric); RTNLMessage message( RTNLMessage::kTypeRoute, RTNLMessage::kModeAdd, NLM_F_REQUEST | NLM_F_CREATE | NLM_F_EXCL, 0, 0, 0, family); message.set_route_status(RTNLMessage::RouteStatus( 0, 0, table_id, RTPROT_BOOT, RT_SCOPE_UNIVERSE, RTN_BLACKHOLE, 0)); message.SetAttribute(RTA_PRIORITY, ByteString::CreateFromCPUUInt32(metric)); message.SetAttribute(RTA_OIF, ByteString::CreateFromCPUUInt32(interface_index)); return rtnl_handler_->SendMessage(&message); } bool RoutingTable::CreateLinkRoute(int interface_index, const IPAddress& local_address, const IPAddress& remote_address, uint8_t table_id) { if (!local_address.CanReachAddress(remote_address)) { LOG(ERROR) << __func__ << " failed: " << remote_address.ToString() << " is not reachable from " << local_address.ToString(); return false; } IPAddress default_address(local_address.family()); default_address.SetAddressToDefault(); IPAddress destination_address(remote_address); destination_address.set_prefix( IPAddress::GetMaxPrefixLength(remote_address.family())); SLOG(this, 2) << "Creating link route to " << destination_address.ToString() << " from " << local_address.ToString() << " on interface index " << interface_index; return AddRoute(interface_index, RoutingTableEntry(destination_address, local_address, default_address, 0, RT_SCOPE_LINK, false, table_id, RoutingTableEntry::kDefaultTag)); } } // namespace shill