/*
* Copyright (C) 2014 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.
*/
// THREAD-SAFETY
// -------------
// The methods in this file are called from multiple threads (from CommandListener, FwmarkServer
// and DnsProxyListener). So, all accesses to shared state are guarded by a lock.
//
// In some cases, a single non-const method acquires and releases the lock several times, like so:
// if (isValidNetwork(...)) { // isValidNetwork() acquires and releases the lock.
// setDefaultNetwork(...); // setDefaultNetwork() also acquires and releases the lock.
//
// It might seem that this allows races where the state changes between the two statements, but in
// fact there are no races because:
// 1. This pattern only occurs in non-const methods (i.e., those that mutate state).
// 2. Only CommandListener calls these non-const methods. The others call only const methods.
// 3. CommandListener only processes one command at a time. I.e., it's serialized.
// Thus, no other mutation can occur in between the two statements above.
#include "NetworkController.h"
#define LOG_TAG "Netd"
#include "log/log.h"
#include "cutils/misc.h"
#include "resolv_netid.h"
#include "Controllers.h"
#include "DummyNetwork.h"
#include "DumpWriter.h"
#include "Fwmark.h"
#include "LocalNetwork.h"
#include "PhysicalNetwork.h"
#include "RouteController.h"
#include "VirtualNetwork.h"
#define DBG 0
namespace android {
namespace net {
namespace {
// Keep these in sync with ConnectivityService.java.
const unsigned MIN_NET_ID = 100;
const unsigned MAX_NET_ID = 65535;
} // namespace
const unsigned NetworkController::MIN_OEM_ID = 1;
const unsigned NetworkController::MAX_OEM_ID = 50;
const unsigned NetworkController::DUMMY_NET_ID = 51;
// NetIds 52..98 are reserved for future use.
const unsigned NetworkController::LOCAL_NET_ID = 99;
// All calls to methods here are made while holding a write lock on mRWLock.
class NetworkController::DelegateImpl : public PhysicalNetwork::Delegate {
public:
explicit DelegateImpl(NetworkController* networkController);
virtual ~DelegateImpl();
int modifyFallthrough(unsigned vpnNetId, const std::string& physicalInterface,
Permission permission, bool add) WARN_UNUSED_RESULT;
private:
int addFallthrough(const std::string& physicalInterface,
Permission permission) override WARN_UNUSED_RESULT;
int removeFallthrough(const std::string& physicalInterface,
Permission permission) override WARN_UNUSED_RESULT;
int modifyFallthrough(const std::string& physicalInterface, Permission permission,
bool add) WARN_UNUSED_RESULT;
NetworkController* const mNetworkController;
};
NetworkController::DelegateImpl::DelegateImpl(NetworkController* networkController) :
mNetworkController(networkController) {
}
NetworkController::DelegateImpl::~DelegateImpl() {
}
int NetworkController::DelegateImpl::modifyFallthrough(unsigned vpnNetId,
const std::string& physicalInterface,
Permission permission, bool add) {
if (add) {
if (int ret = RouteController::addVirtualNetworkFallthrough(vpnNetId,
physicalInterface.c_str(),
permission)) {
ALOGE("failed to add fallthrough to %s for VPN netId %u", physicalInterface.c_str(),
vpnNetId);
return ret;
}
} else {
if (int ret = RouteController::removeVirtualNetworkFallthrough(vpnNetId,
physicalInterface.c_str(),
permission)) {
ALOGE("failed to remove fallthrough to %s for VPN netId %u", physicalInterface.c_str(),
vpnNetId);
return ret;
}
}
return 0;
}
int NetworkController::DelegateImpl::addFallthrough(const std::string& physicalInterface,
Permission permission) {
return modifyFallthrough(physicalInterface, permission, true);
}
int NetworkController::DelegateImpl::removeFallthrough(const std::string& physicalInterface,
Permission permission) {
return modifyFallthrough(physicalInterface, permission, false);
}
int NetworkController::DelegateImpl::modifyFallthrough(const std::string& physicalInterface,
Permission permission, bool add) {
for (const auto& entry : mNetworkController->mNetworks) {
if (entry.second->getType() == Network::VIRTUAL) {
if (int ret = modifyFallthrough(entry.first, physicalInterface, permission, add)) {
return ret;
}
}
}
return 0;
}
NetworkController::NetworkController() :
mDelegateImpl(new NetworkController::DelegateImpl(this)), mDefaultNetId(NETID_UNSET),
mProtectableUsers({AID_VPN}) {
mNetworks[LOCAL_NET_ID] = new LocalNetwork(LOCAL_NET_ID);
mNetworks[DUMMY_NET_ID] = new DummyNetwork(DUMMY_NET_ID);
}
unsigned NetworkController::getDefaultNetwork() const {
android::RWLock::AutoRLock lock(mRWLock);
return mDefaultNetId;
}
int NetworkController::setDefaultNetwork(unsigned netId) {
android::RWLock::AutoWLock lock(mRWLock);
if (netId == mDefaultNetId) {
return 0;
}
if (netId != NETID_UNSET) {
Network* network = getNetworkLocked(netId);
if (!network) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
if (network->getType() != Network::PHYSICAL) {
ALOGE("cannot set default to non-physical network with netId %u", netId);
return -EINVAL;
}
if (int ret = static_cast<PhysicalNetwork*>(network)->addAsDefault()) {
return ret;
}
}
if (mDefaultNetId != NETID_UNSET) {
Network* network = getNetworkLocked(mDefaultNetId);
if (!network || network->getType() != Network::PHYSICAL) {
ALOGE("cannot find previously set default network with netId %u", mDefaultNetId);
return -ESRCH;
}
if (int ret = static_cast<PhysicalNetwork*>(network)->removeAsDefault()) {
return ret;
}
}
mDefaultNetId = netId;
return 0;
}
uint32_t NetworkController::getNetworkForDns(unsigned* netId, uid_t uid) const {
android::RWLock::AutoRLock lock(mRWLock);
Fwmark fwmark;
fwmark.protectedFromVpn = true;
fwmark.permission = PERMISSION_SYSTEM;
if (checkUserNetworkAccessLocked(uid, *netId) == 0) {
// If a non-zero NetId was explicitly specified, and the user has permission for that
// network, use that network's DNS servers. Do not fall through to the default network even
// if the explicitly selected network is a split tunnel VPN: the explicitlySelected bit
// ensures that the VPN fallthrough rule does not match.
fwmark.explicitlySelected = true;
// If the network is a VPN and it doesn't have DNS servers, use the default network's DNS
// servers (through the default network). Otherwise, the query is guaranteed to fail.
// http://b/29498052
Network *network = getNetworkLocked(*netId);
if (network && network->getType() == Network::VIRTUAL &&
!static_cast<VirtualNetwork *>(network)->getHasDns()) {
*netId = mDefaultNetId;
}
} else {
// If the user is subject to a VPN and the VPN provides DNS servers, use those servers
// (possibly falling through to the default network if the VPN doesn't provide a route to
// them). Otherwise, use the default network's DNS servers.
VirtualNetwork* virtualNetwork = getVirtualNetworkForUserLocked(uid);
if (virtualNetwork && virtualNetwork->getHasDns()) {
*netId = virtualNetwork->getNetId();
} else {
// TODO: return an error instead of silently doing the DNS lookup on the wrong network.
// http://b/27560555
*netId = mDefaultNetId;
}
}
fwmark.netId = *netId;
return fwmark.intValue;
}
// Returns the NetId that a given UID would use if no network is explicitly selected. Specifically,
// the VPN that applies to the UID if any; otherwise, the default network.
unsigned NetworkController::getNetworkForUser(uid_t uid) const {
android::RWLock::AutoRLock lock(mRWLock);
if (VirtualNetwork* virtualNetwork = getVirtualNetworkForUserLocked(uid)) {
return virtualNetwork->getNetId();
}
return mDefaultNetId;
}
// Returns the NetId that will be set when a socket connect()s. This is the bypassable VPN that
// applies to the user if any; otherwise, the default network.
//
// In general, we prefer to always set the default network's NetId in connect(), so that if the VPN
// is a split-tunnel and disappears later, the socket continues working (since the default network's
// NetId is still valid). Secure VPNs will correctly grab the socket's traffic since they have a
// high-priority routing rule that doesn't care what NetId the socket has.
//
// But bypassable VPNs have a very low priority rule, so we need to mark the socket with the
// bypassable VPN's NetId if we expect it to get any traffic at all. If the bypassable VPN is a
// split-tunnel, that's okay, because we have fallthrough rules that will direct the fallthrough
// traffic to the default network. But it does mean that if the bypassable VPN goes away (and thus
// the fallthrough rules also go away), the socket that used to fallthrough to the default network
// will stop working.
unsigned NetworkController::getNetworkForConnect(uid_t uid) const {
android::RWLock::AutoRLock lock(mRWLock);
VirtualNetwork* virtualNetwork = getVirtualNetworkForUserLocked(uid);
if (virtualNetwork && !virtualNetwork->isSecure()) {
return virtualNetwork->getNetId();
}
return mDefaultNetId;
}
void NetworkController::getNetworkContext(
unsigned netId, uid_t uid, struct android_net_context* netcontext) const {
struct android_net_context nc = {
.app_netid = netId,
.app_mark = MARK_UNSET,
.dns_netid = netId,
.dns_mark = MARK_UNSET,
.uid = uid,
};
// |netId| comes directly (via dnsproxyd) from the value returned by netIdForResolv() in the
// client process. This value is nonzero iff.:
//
// 1. The app specified a netid/nethandle to a DNS resolution method such as:
// - [Java] android.net.Network#getAllByName()
// - [C/++] android_getaddrinfofornetwork()
// 2. The app specified a netid/nethandle to be used as a process default via:
// - [Java] android.net.ConnectivityManager#bindProcessToNetwork()
// - [C/++] android_setprocnetwork()
// 3. The app called android.net.ConnectivityManager#startUsingNetworkFeature().
//
// In all these cases (with the possible exception of #3), the right thing to do is to treat
// such cases as explicitlySelected.
const bool explicitlySelected = (nc.app_netid != NETID_UNSET);
if (!explicitlySelected) {
nc.app_netid = getNetworkForConnect(uid);
}
Fwmark fwmark;
fwmark.netId = nc.app_netid;
fwmark.explicitlySelected = explicitlySelected;
fwmark.protectedFromVpn = explicitlySelected && canProtect(uid);
fwmark.permission = getPermissionForUser(uid);
nc.app_mark = fwmark.intValue;
nc.dns_mark = getNetworkForDns(&(nc.dns_netid), uid);
if (DBG) {
ALOGD("app_netid:0x%x app_mark:0x%x dns_netid:0x%x dns_mark:0x%x uid:%d",
nc.app_netid, nc.app_mark, nc.dns_netid, nc.dns_mark, uid);
}
if (netcontext) {
*netcontext = nc;
}
}
unsigned NetworkController::getNetworkForInterface(const char* interface) const {
android::RWLock::AutoRLock lock(mRWLock);
for (const auto& entry : mNetworks) {
if (entry.second->hasInterface(interface)) {
return entry.first;
}
}
return NETID_UNSET;
}
bool NetworkController::isVirtualNetwork(unsigned netId) const {
android::RWLock::AutoRLock lock(mRWLock);
Network* network = getNetworkLocked(netId);
return network && network->getType() == Network::VIRTUAL;
}
int NetworkController::createPhysicalNetwork(unsigned netId, Permission permission) {
if (!((MIN_NET_ID <= netId && netId <= MAX_NET_ID) ||
(MIN_OEM_ID <= netId && netId <= MAX_OEM_ID))) {
ALOGE("invalid netId %u", netId);
return -EINVAL;
}
if (isValidNetwork(netId)) {
ALOGE("duplicate netId %u", netId);
return -EEXIST;
}
PhysicalNetwork* physicalNetwork = new PhysicalNetwork(netId, mDelegateImpl);
if (int ret = physicalNetwork->setPermission(permission)) {
ALOGE("inconceivable! setPermission cannot fail on an empty network");
delete physicalNetwork;
return ret;
}
android::RWLock::AutoWLock lock(mRWLock);
mNetworks[netId] = physicalNetwork;
return 0;
}
int NetworkController::createVirtualNetwork(unsigned netId, bool hasDns, bool secure) {
if (!(MIN_NET_ID <= netId && netId <= MAX_NET_ID)) {
ALOGE("invalid netId %u", netId);
return -EINVAL;
}
if (isValidNetwork(netId)) {
ALOGE("duplicate netId %u", netId);
return -EEXIST;
}
android::RWLock::AutoWLock lock(mRWLock);
if (int ret = modifyFallthroughLocked(netId, true)) {
return ret;
}
mNetworks[netId] = new VirtualNetwork(netId, hasDns, secure);
return 0;
}
int NetworkController::destroyNetwork(unsigned netId) {
if (netId == LOCAL_NET_ID) {
ALOGE("cannot destroy local network");
return -EINVAL;
}
if (!isValidNetwork(netId)) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
// TODO: ioctl(SIOCKILLADDR, ...) to kill all sockets on the old network.
android::RWLock::AutoWLock lock(mRWLock);
Network* network = getNetworkLocked(netId);
// If we fail to destroy a network, things will get stuck badly. Therefore, unlike most of the
// other network code, ignore failures and attempt to clear out as much state as possible, even
// if we hit an error on the way. Return the first error that we see.
int ret = network->clearInterfaces();
if (mDefaultNetId == netId) {
if (int err = static_cast<PhysicalNetwork*>(network)->removeAsDefault()) {
ALOGE("inconceivable! removeAsDefault cannot fail on an empty network");
if (!ret) {
ret = err;
}
}
mDefaultNetId = NETID_UNSET;
} else if (network->getType() == Network::VIRTUAL) {
if (int err = modifyFallthroughLocked(netId, false)) {
if (!ret) {
ret = err;
}
}
}
mNetworks.erase(netId);
delete network;
_resolv_delete_cache_for_net(netId);
return ret;
}
int NetworkController::addInterfaceToNetwork(unsigned netId, const char* interface) {
if (!isValidNetwork(netId)) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
unsigned existingNetId = getNetworkForInterface(interface);
if (existingNetId != NETID_UNSET && existingNetId != netId) {
ALOGE("interface %s already assigned to netId %u", interface, existingNetId);
return -EBUSY;
}
android::RWLock::AutoWLock lock(mRWLock);
return getNetworkLocked(netId)->addInterface(interface);
}
int NetworkController::removeInterfaceFromNetwork(unsigned netId, const char* interface) {
if (!isValidNetwork(netId)) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
android::RWLock::AutoWLock lock(mRWLock);
return getNetworkLocked(netId)->removeInterface(interface);
}
Permission NetworkController::getPermissionForUser(uid_t uid) const {
android::RWLock::AutoRLock lock(mRWLock);
return getPermissionForUserLocked(uid);
}
void NetworkController::setPermissionForUsers(Permission permission,
const std::vector<uid_t>& uids) {
android::RWLock::AutoWLock lock(mRWLock);
for (uid_t uid : uids) {
mUsers[uid] = permission;
}
}
int NetworkController::checkUserNetworkAccess(uid_t uid, unsigned netId) const {
android::RWLock::AutoRLock lock(mRWLock);
return checkUserNetworkAccessLocked(uid, netId);
}
int NetworkController::setPermissionForNetworks(Permission permission,
const std::vector<unsigned>& netIds) {
android::RWLock::AutoWLock lock(mRWLock);
for (unsigned netId : netIds) {
Network* network = getNetworkLocked(netId);
if (!network) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
if (network->getType() != Network::PHYSICAL) {
ALOGE("cannot set permissions on non-physical network with netId %u", netId);
return -EINVAL;
}
if (int ret = static_cast<PhysicalNetwork*>(network)->setPermission(permission)) {
return ret;
}
}
return 0;
}
int NetworkController::addUsersToNetwork(unsigned netId, const UidRanges& uidRanges) {
android::RWLock::AutoWLock lock(mRWLock);
Network* network = getNetworkLocked(netId);
if (!network) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
if (network->getType() != Network::VIRTUAL) {
ALOGE("cannot add users to non-virtual network with netId %u", netId);
return -EINVAL;
}
if (int ret = static_cast<VirtualNetwork*>(network)->addUsers(uidRanges, mProtectableUsers)) {
return ret;
}
return 0;
}
int NetworkController::removeUsersFromNetwork(unsigned netId, const UidRanges& uidRanges) {
android::RWLock::AutoWLock lock(mRWLock);
Network* network = getNetworkLocked(netId);
if (!network) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
if (network->getType() != Network::VIRTUAL) {
ALOGE("cannot remove users from non-virtual network with netId %u", netId);
return -EINVAL;
}
if (int ret = static_cast<VirtualNetwork*>(network)->removeUsers(uidRanges,
mProtectableUsers)) {
return ret;
}
return 0;
}
int NetworkController::addRoute(unsigned netId, const char* interface, const char* destination,
const char* nexthop, bool legacy, uid_t uid) {
return modifyRoute(netId, interface, destination, nexthop, true, legacy, uid);
}
int NetworkController::removeRoute(unsigned netId, const char* interface, const char* destination,
const char* nexthop, bool legacy, uid_t uid) {
return modifyRoute(netId, interface, destination, nexthop, false, legacy, uid);
}
bool NetworkController::canProtect(uid_t uid) const {
android::RWLock::AutoRLock lock(mRWLock);
return ((getPermissionForUserLocked(uid) & PERMISSION_SYSTEM) == PERMISSION_SYSTEM) ||
mProtectableUsers.find(uid) != mProtectableUsers.end();
}
void NetworkController::allowProtect(const std::vector<uid_t>& uids) {
android::RWLock::AutoWLock lock(mRWLock);
mProtectableUsers.insert(uids.begin(), uids.end());
}
void NetworkController::denyProtect(const std::vector<uid_t>& uids) {
android::RWLock::AutoWLock lock(mRWLock);
for (uid_t uid : uids) {
mProtectableUsers.erase(uid);
}
}
void NetworkController::dump(DumpWriter& dw) {
android::RWLock::AutoRLock lock(mRWLock);
dw.incIndent();
dw.println("NetworkController");
dw.incIndent();
dw.println("Default network: %u", mDefaultNetId);
dw.blankline();
dw.println("Networks:");
dw.incIndent();
for (const auto& i : mNetworks) {
Network* network = i.second;
dw.println(network->toString().c_str());
if (network->getType() == Network::PHYSICAL) {
dw.incIndent();
Permission permission = reinterpret_cast<PhysicalNetwork*>(network)->getPermission();
dw.println("Required permission: %s", permissionToName(permission));
dw.decIndent();
}
android::net::gCtls->resolverCtrl.dump(dw, i.first);
dw.blankline();
}
dw.decIndent();
dw.decIndent();
dw.decIndent();
}
bool NetworkController::isValidNetwork(unsigned netId) const {
android::RWLock::AutoRLock lock(mRWLock);
return getNetworkLocked(netId);
}
Network* NetworkController::getNetworkLocked(unsigned netId) const {
auto iter = mNetworks.find(netId);
return iter == mNetworks.end() ? NULL : iter->second;
}
VirtualNetwork* NetworkController::getVirtualNetworkForUserLocked(uid_t uid) const {
for (const auto& entry : mNetworks) {
if (entry.second->getType() == Network::VIRTUAL) {
VirtualNetwork* virtualNetwork = static_cast<VirtualNetwork*>(entry.second);
if (virtualNetwork->appliesToUser(uid)) {
return virtualNetwork;
}
}
}
return NULL;
}
Permission NetworkController::getPermissionForUserLocked(uid_t uid) const {
auto iter = mUsers.find(uid);
if (iter != mUsers.end()) {
return iter->second;
}
return uid < FIRST_APPLICATION_UID ? PERMISSION_SYSTEM : PERMISSION_NONE;
}
int NetworkController::checkUserNetworkAccessLocked(uid_t uid, unsigned netId) const {
Network* network = getNetworkLocked(netId);
if (!network) {
return -ENONET;
}
// If uid is INVALID_UID, this likely means that we were unable to retrieve the UID of the peer
// (using SO_PEERCRED). Be safe and deny access to the network, even if it's valid.
if (uid == INVALID_UID) {
return -EREMOTEIO;
}
Permission userPermission = getPermissionForUserLocked(uid);
if ((userPermission & PERMISSION_SYSTEM) == PERMISSION_SYSTEM) {
return 0;
}
if (network->getType() == Network::VIRTUAL) {
return static_cast<VirtualNetwork*>(network)->appliesToUser(uid) ? 0 : -EPERM;
}
VirtualNetwork* virtualNetwork = getVirtualNetworkForUserLocked(uid);
if (virtualNetwork && virtualNetwork->isSecure() &&
mProtectableUsers.find(uid) == mProtectableUsers.end()) {
return -EPERM;
}
Permission networkPermission = static_cast<PhysicalNetwork*>(network)->getPermission();
return ((userPermission & networkPermission) == networkPermission) ? 0 : -EACCES;
}
int NetworkController::modifyRoute(unsigned netId, const char* interface, const char* destination,
const char* nexthop, bool add, bool legacy, uid_t uid) {
if (!isValidNetwork(netId)) {
ALOGE("no such netId %u", netId);
return -ENONET;
}
unsigned existingNetId = getNetworkForInterface(interface);
if (existingNetId == NETID_UNSET) {
ALOGE("interface %s not assigned to any netId", interface);
return -ENODEV;
}
if (existingNetId != netId) {
ALOGE("interface %s assigned to netId %u, not %u", interface, existingNetId, netId);
return -ENOENT;
}
RouteController::TableType tableType;
if (netId == LOCAL_NET_ID) {
tableType = RouteController::LOCAL_NETWORK;
} else if (legacy) {
if ((getPermissionForUser(uid) & PERMISSION_SYSTEM) == PERMISSION_SYSTEM) {
tableType = RouteController::LEGACY_SYSTEM;
} else {
tableType = RouteController::LEGACY_NETWORK;
}
} else {
tableType = RouteController::INTERFACE;
}
return add ? RouteController::addRoute(interface, destination, nexthop, tableType) :
RouteController::removeRoute(interface, destination, nexthop, tableType);
}
int NetworkController::modifyFallthroughLocked(unsigned vpnNetId, bool add) {
if (mDefaultNetId == NETID_UNSET) {
return 0;
}
Network* network = getNetworkLocked(mDefaultNetId);
if (!network) {
ALOGE("cannot find previously set default network with netId %u", mDefaultNetId);
return -ESRCH;
}
if (network->getType() != Network::PHYSICAL) {
ALOGE("inconceivable! default network must be a physical network");
return -EINVAL;
}
Permission permission = static_cast<PhysicalNetwork*>(network)->getPermission();
for (const auto& physicalInterface : network->getInterfaces()) {
if (int ret = mDelegateImpl->modifyFallthrough(vpnNetId, physicalInterface, permission,
add)) {
return ret;
}
}
return 0;
}
} // namespace net
} // namespace android