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|
// Copyright (C) 2011-2020 Internet Systems Consortium, Inc. ("ISC")
//
// This Source Code Form is subject to the terms of the Mozilla Public
// License, v. 2.0. If a copy of the MPL was not distributed with this
// file, You can obtain one at http://mozilla.org/MPL/2.0/.
#include <config.h>
#include <asiolink/asio_wrapper.h>
#include <asiolink/io_error.h>
#include <asiolink/udp_endpoint.h>
#include <dhcp/dhcp4.h>
#include <dhcp/dhcp6.h>
#include <dhcp/iface_mgr.h>
#include <dhcp/iface_mgr_error_handler.h>
#include <dhcp/pkt_filter_inet.h>
#include <dhcp/pkt_filter_inet6.h>
#include <exceptions/exceptions.h>
#include <util/io/pktinfo_utilities.h>
#include <util/multi_threading_mgr.h>
#include <boost/scoped_ptr.hpp>
#include <cstring>
#include <errno.h>
#include <fstream>
#include <functional>
#include <limits>
#include <sstream>
#include <arpa/inet.h>
#include <netinet/in.h>
#include <string.h>
#include <sys/ioctl.h>
#include <sys/select.h>
#ifndef FD_COPY
#define FD_COPY(orig, copy) \
do { \
memmove(copy, orig, sizeof(fd_set)); \
} while (0)
#endif
using namespace std;
using namespace isc::asiolink;
using namespace isc::util;
using namespace isc::util::io;
using namespace isc::util::io::internal;
namespace isc {
namespace dhcp {
IfaceMgr&
IfaceMgr::instance() {
return (*instancePtr());
}
const IfaceMgrPtr&
IfaceMgr::instancePtr() {
static IfaceMgrPtr iface_mgr(new IfaceMgr());
return (iface_mgr);
}
Iface::Iface(const std::string& name, unsigned int ifindex)
:name_(name), ifindex_(ifindex), mac_len_(0), hardware_type_(0),
flag_loopback_(false), flag_up_(false), flag_running_(false),
flag_multicast_(false), flag_broadcast_(false), flags_(0),
inactive4_(false), inactive6_(false)
{
// Sanity checks.
if (name.empty()) {
isc_throw(BadValue, "Interface name must not be empty");
}
memset(mac_, 0, sizeof(mac_));
}
void
Iface::closeSockets() {
// Close IPv4 sockets.
closeSockets(AF_INET);
// Close IPv6 sockets.
closeSockets(AF_INET6);
}
void
Iface::closeSockets(const uint16_t family) {
// Check that the correct 'family' value has been specified.
// The possible values are AF_INET or AF_INET6. Note that, in
// the current code they are used to differentiate that the
// socket is used to transmit IPv4 or IPv6 traffic. However,
// the actual family types of the sockets may be different,
// e.g. for LPF we are using raw sockets of AF_PACKET family.
//
// @todo Consider replacing the AF_INET and AF_INET6 with some
// enum which will not be confused with the actual socket type.
if ((family != AF_INET) && (family != AF_INET6)) {
isc_throw(BadValue, "Invalid socket family " << family
<< " specified when requested to close all sockets"
<< " which belong to this family");
}
// Search for the socket of the specific type.
SocketCollection::iterator sock = sockets_.begin();
while (sock != sockets_.end()) {
if (sock->family_ == family) {
// Close and delete the socket and move to the
// next one.
close(sock->sockfd_);
// Close fallback socket if open.
if (sock->fallbackfd_ >= 0) {
close(sock->fallbackfd_);
}
sockets_.erase(sock++);
} else {
// Different type of socket. Let's move
// to the next one.
++sock;
}
}
}
std::string
Iface::getFullName() const {
ostringstream tmp;
tmp << name_ << "/" << ifindex_;
return (tmp.str());
}
std::string
Iface::getPlainMac() const {
ostringstream tmp;
tmp.fill('0');
tmp << hex;
for (int i = 0; i < mac_len_; i++) {
tmp.width(2);
tmp << static_cast<int>(mac_[i]);
if (i < mac_len_-1) {
tmp << ":";
}
}
return (tmp.str());
}
void Iface::setMac(const uint8_t* mac, size_t len) {
if (len > MAX_MAC_LEN) {
isc_throw(OutOfRange, "Interface " << getFullName()
<< " was detected to have link address of length "
<< len << ", but maximum supported length is "
<< MAX_MAC_LEN);
}
mac_len_ = len;
if (len > 0) {
memcpy(mac_, mac, len);
}
}
bool Iface::delAddress(const isc::asiolink::IOAddress& addr) {
for (AddressCollection::iterator a = addrs_.begin();
a!=addrs_.end(); ++a) {
if (a->get() == addr) {
addrs_.erase(a);
return (true);
}
}
return (false);
}
bool Iface::delSocket(const uint16_t sockfd) {
list<SocketInfo>::iterator sock = sockets_.begin();
while (sock!=sockets_.end()) {
if (sock->sockfd_ == sockfd) {
close(sockfd);
// Close fallback socket if open.
if (sock->fallbackfd_ >= 0) {
close(sock->fallbackfd_);
}
sockets_.erase(sock);
return (true); //socket found
}
++sock;
}
return (false); // socket not found
}
IfaceMgr::IfaceMgr()
: packet_filter_(new PktFilterInet()),
packet_filter6_(new PktFilterInet6()),
test_mode_(false),
allow_loopback_(false) {
// Ensure that PQMs have been created to guarantee we have
// default packet queues in place.
try {
packet_queue_mgr4_.reset(new PacketQueueMgr4());
packet_queue_mgr6_.reset(new PacketQueueMgr6());
} catch (const std::exception& ex) {
isc_throw(Unexpected, "Failed to create PacketQueueManagers: " << ex.what());
}
try {
// required for sending/receiving packets
// let's keep it in front, just in case someone
// wants to send anything during initialization
detectIfaces();
} catch (const std::exception& ex) {
isc_throw(IfaceDetectError, ex.what());
}
}
void Iface::addUnicast(const isc::asiolink::IOAddress& addr) {
for (Address a : unicasts_) {
if (a.get() == addr) {
isc_throw(BadValue, "Address " << addr
<< " already defined on the " << name_ << " interface.");
}
}
unicasts_.push_back(Optional<IOAddress>(addr));
}
bool
Iface::getAddress4(isc::asiolink::IOAddress& address) const {
// Iterate over existing addresses assigned to the interface.
// Try to find the one that is IPv4.
for (Address addr : getAddresses()) {
// If address is IPv4, we assign it to the function argument
// and return true.
if (addr.get().isV4()) {
address = addr.get();
return (true);
}
}
// There is no IPv4 address assigned to this interface.
return (false);
}
bool
Iface::hasAddress(const isc::asiolink::IOAddress& address) const {
for (Address addr : getAddresses()) {
if (address == addr.get()) {
return (true);
}
}
return (false);
}
void
Iface::addAddress(const isc::asiolink::IOAddress& addr) {
addrs_.push_back(Address(addr));
}
void
Iface::setActive(const IOAddress& address, const bool active) {
for (AddressCollection::iterator addr_it = addrs_.begin();
addr_it != addrs_.end(); ++addr_it) {
if (address == addr_it->get()) {
addr_it->unspecified(!active);
return;
}
}
isc_throw(BadValue, "specified address " << address << " was not"
" found on the interface " << getName());
}
void
Iface::setActive(const bool active) {
for (AddressCollection::iterator addr_it = addrs_.begin();
addr_it != addrs_.end(); ++addr_it) {
addr_it->unspecified(!active);
}
}
unsigned int
Iface::countActive4() const {
uint16_t count = 0;
for (Address addr : addrs_) {
if (!addr.unspecified() && addr.get().isV4()) {
++count;
}
}
return (count);
}
void IfaceMgr::closeSockets() {
// Clears bound addresses.
clearBoundAddresses();
// Stops the receiver thread if there is one.
stopDHCPReceiver();
for (IfacePtr iface : ifaces_) {
iface->closeSockets();
}
}
void IfaceMgr::stopDHCPReceiver() {
if (isDHCPReceiverRunning()) {
dhcp_receiver_->stop();
}
dhcp_receiver_.reset();
if (getPacketQueue4()) {
getPacketQueue4()->clear();
}
if (getPacketQueue6()) {
getPacketQueue6()->clear();
}
}
IfaceMgr::~IfaceMgr() {
closeSockets();
}
bool
IfaceMgr::isDirectResponseSupported() const {
return (packet_filter_->isDirectResponseSupported());
}
void
IfaceMgr::addExternalSocket(int socketfd, SocketCallback callback) {
if (socketfd < 0) {
isc_throw(BadValue, "Attempted to install callback for invalid socket "
<< socketfd);
}
std::lock_guard<std::mutex> lock(callbacks_mutex_);
for (SocketCallbackInfo s : callbacks_) {
// There's such a socket description there already.
// Update the callback and we're done
if (s.socket_ == socketfd) {
s.callback_ = callback;
return;
}
}
// Add a new entry to the callbacks vector
SocketCallbackInfo x;
x.socket_ = socketfd;
x.callback_ = callback;
callbacks_.push_back(x);
}
void
IfaceMgr::deleteExternalSocket(int socketfd) {
std::lock_guard<std::mutex> lock(callbacks_mutex_);
deleteExternalSocketInternal(socketfd);
}
void
IfaceMgr::deleteExternalSocketInternal(int socketfd) {
for (SocketCallbackInfoContainer::iterator s = callbacks_.begin();
s != callbacks_.end(); ++s) {
if (s->socket_ == socketfd) {
callbacks_.erase(s);
return;
}
}
}
int
IfaceMgr::purgeBadSockets() {
std::lock_guard<std::mutex> lock(callbacks_mutex_);
std::vector<int> bad_fds;
for (SocketCallbackInfo s : callbacks_) {
errno = 0;
if (fcntl(s.socket_, F_GETFD) < 0 && (errno == EBADF)) {
bad_fds.push_back(s.socket_);
}
}
for (auto bad_fd : bad_fds) {
deleteExternalSocketInternal(bad_fd);
}
return (bad_fds.size());
}
void
IfaceMgr::deleteAllExternalSockets() {
std::lock_guard<std::mutex> lock(callbacks_mutex_);
callbacks_.clear();
}
void
IfaceMgr::setPacketFilter(const PktFilterPtr& packet_filter) {
// Do not allow null pointer.
if (!packet_filter) {
isc_throw(InvalidPacketFilter, "NULL packet filter object specified for"
" DHCPv4");
}
// Different packet filters use different socket types. It does not make
// sense to allow the change of packet filter when there are IPv4 sockets
// open because they can't be used by the receive/send functions of the
// new packet filter. Below, we check that there are no open IPv4 sockets.
// If we find at least one, we have to fail. However, caller still has a
// chance to replace the packet filter if he closes sockets explicitly.
if (hasOpenSocket(AF_INET)) {
// There is at least one socket open, so we have to fail.
isc_throw(PacketFilterChangeDenied,
"it is not allowed to set new packet"
<< " filter when there are open IPv4 sockets - need"
<< " to close them first");
}
// Everything is fine, so replace packet filter.
packet_filter_ = packet_filter;
}
void
IfaceMgr::setPacketFilter(const PktFilter6Ptr& packet_filter) {
if (!packet_filter) {
isc_throw(InvalidPacketFilter, "NULL packet filter object specified for"
" DHCPv6");
}
if (hasOpenSocket(AF_INET6)) {
// There is at least one socket open, so we have to fail.
isc_throw(PacketFilterChangeDenied,
"it is not allowed to set new packet"
<< " filter when there are open IPv6 sockets - need"
<< " to close them first");
}
packet_filter6_ = packet_filter;
}
bool
IfaceMgr::hasOpenSocket(const uint16_t family) const {
// Iterate over all interfaces and search for open sockets.
for (IfacePtr iface : ifaces_) {
for (SocketInfo sock : iface->getSockets()) {
// Check if the socket matches specified family.
if (sock.family_ == family) {
// There is at least one socket open, so return.
return (true);
}
}
}
// There are no open sockets found for the specified family.
return (false);
}
bool
IfaceMgr::hasOpenSocket(const IOAddress& addr) const {
// Fast track for IPv4 using bound addresses.
if (addr.isV4() && !bound_address_.empty()) {
return (bound_address_.count(addr.toUint32()) != 0);
}
// Iterate over all interfaces and search for open sockets.
for (IfacePtr iface : ifaces_) {
for (SocketInfo sock : iface->getSockets()) {
// Check if the socket address matches the specified address or
// if address is unspecified (in6addr_any).
if (sock.addr_ == addr) {
return (true);
} else if (sock.addr_.isV6Zero()) {
// Handle the case that the address is unspecified (any).
// This happens only with IPv6 so we do not check IPv4.
// In this case, we should check if the specified address
// belongs to any of the interfaces.
for (IfacePtr it : ifaces_) {
for (Iface::Address a : it->getAddresses()) {
if (addr == a.get()) {
return (true);
}
}
}
// The address does not belongs to any interface.
return (false);
}
}
}
// There are no open sockets found for the specified family.
return (false);
}
void IfaceMgr::stubDetectIfaces() {
string ifaceName;
const string v4addr("127.0.0.1"), v6addr("::1");
// This is a stub implementation for interface detection. Actual detection
// is faked by detecting loopback interface (lo or lo0). It will eventually
// be removed once we have actual implementations for all supported systems.
if (if_nametoindex("lo") > 0) {
ifaceName = "lo";
// this is Linux-like OS
} else if (if_nametoindex("lo0") > 0) {
ifaceName = "lo0";
// this is BSD-like OS
} else {
// we give up. What OS is this, anyway? Solaris? Hurd?
isc_throw(NotImplemented,
"Interface detection on this OS is not supported.");
}
IfacePtr iface(new Iface(ifaceName, if_nametoindex(ifaceName.c_str())));
iface->flag_up_ = true;
iface->flag_running_ = true;
// Note that we claim that this is not a loopback. iface_mgr tries to open a
// socket on all interfaces that are up, running and not loopback. As this is
// the only interface we were able to detect, let's pretend this is a normal
// interface.
iface->flag_loopback_ = false;
iface->flag_multicast_ = true;
iface->flag_broadcast_ = true;
iface->setHWType(HWTYPE_ETHERNET);
iface->addAddress(IOAddress(v4addr));
iface->addAddress(IOAddress(v6addr));
addInterface(iface);
}
bool
IfaceMgr::openSockets4(const uint16_t port, const bool use_bcast,
IfaceMgrErrorMsgCallback error_handler) {
int count = 0;
int bcast_num = 0;
for (IfacePtr iface : ifaces_) {
// If the interface is inactive, there is nothing to do. Simply
// proceed to the next detected interface.
if (iface->inactive4_) {
continue;
} else {
// If the interface has been specified in the configuration that
// it should be used to listen the DHCP traffic we have to check
// that the interface configuration is valid and that the interface
// is not a loopback interface. In both cases, we want to report
// that the socket will not be opened.
// Relax the check when the loopback interface was explicitely
// allowed
if (iface->flag_loopback_ && !allow_loopback_) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"must not open socket on the loopback"
" interface " << iface->getName());
continue;
}
if (!iface->flag_up_) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"the interface " << iface->getName()
<< " is down");
continue;
}
if (!iface->flag_running_) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"the interface " << iface->getName()
<< " is not running");
continue;
}
IOAddress out_address("0.0.0.0");
if (!iface->getAddress4(out_address)) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"the interface " << iface->getName()
<< " has no usable IPv4 addresses configured");
continue;
}
}
for (Iface::Address addr : iface->getAddresses()) {
// Skip non-IPv4 addresses and those that weren't selected..
if (addr.unspecified() || !addr.get().isV4()) {
continue;
}
// If selected interface is broadcast capable set appropriate
// options on the socket so as it can receive and send broadcast
// messages.
if (iface->flag_broadcast_ && use_bcast) {
// The DHCP server must have means to determine which interface
// the broadcast packets are coming from. This is achieved by
// binding a socket to the device (interface) and specialized
// packet filters (e.g. BPF and LPF) implement this mechanism.
// If the PktFilterInet (generic one) is used, the socket is
// bound to INADDR_ANY which effectively binds the socket to
// all addresses on all interfaces. So, only one of those can
// be opened. Currently, the direct response support is
// provided by the PktFilterLPF and PktFilterBPF, so by checking
// the support for direct response we actually determine that
// one of those objects is in use. For all other objects we
// assume that binding to the device is not supported and we
// cease opening sockets and display the appropriate message.
if (!isDirectResponseSupported() && bcast_num > 0) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"Binding socket to an interface is not"
" supported on this OS; therefore only"
" one socket listening to broadcast traffic"
" can be opened. Sockets will not be opened"
" on remaining interfaces");
continue;
} else {
try {
// We haven't open any broadcast sockets yet, so we can
// open at least one more.
openSocket(iface->getName(), addr.get(), port, true, true);
} catch (const Exception& ex) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"failed to open socket on interface "
<< iface->getName() << ", reason: "
<< ex.what());
continue;
}
// Binding socket to an interface is not supported so we
// can't open any more broadcast sockets. Increase the
// number of open broadcast sockets.
++bcast_num;
}
} else {
try {
// Not broadcast capable, do not set broadcast flags.
openSocket(iface->getName(), addr.get(), port, false, false);
} catch (const Exception& ex) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"failed to open socket on interface "
<< iface->getName() << ", reason: "
<< ex.what());
continue;
}
}
++count;
}
}
// If we have open sockets, start the receiver.
if (count > 0) {
// Collects bound addresses.
collectBoundAddresses();
// Starts the receiver thread (if queueing is enabled).
startDHCPReceiver(AF_INET);
}
return (count > 0);
}
bool
IfaceMgr::openSockets6(const uint16_t port,
IfaceMgrErrorMsgCallback error_handler) {
int count = 0;
for (IfacePtr iface : ifaces_) {
if (iface->inactive6_) {
continue;
} else {
// If the interface has been specified in the configuration that
// it should be used to listen the DHCP traffic we have to check
// that the interface configuration is valid and that the interface
// is not a loopback interface. In both cases, we want to report
// that the socket will not be opened.
// Relax the check when the loopback interface was explicitely
// allowed
if (iface->flag_loopback_ && !allow_loopback_) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"must not open socket on the loopback"
" interface " << iface->getName());
continue;
} else if (!iface->flag_up_) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"the interface " << iface->getName()
<< " is down");
continue;
} else if (!iface->flag_running_) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"the interface " << iface->getName()
<< " is not running");
continue;
}
}
// Open unicast sockets if there are any unicast addresses defined
for (Iface::Address addr : iface->getUnicasts()) {
try {
openSocket(iface->getName(), addr, port);
} catch (const Exception& ex) {
IFACEMGR_ERROR(SocketConfigError, error_handler,
"Failed to open unicast socket on interface "
<< iface->getName() << ", reason: "
<< ex.what());
continue;
}
count++;
}
for (Iface::Address addr : iface->getAddresses()) {
// Skip all but V6 addresses.
if (!addr.get().isV6()) {
continue;
}
// Bind link-local addresses only. Otherwise we bind several sockets
// on interfaces that have several global addresses. For examples
// with interface with 2 global addresses, we would bind 3 sockets
// (one for link-local and two for global). That would result in
// getting each message 3 times.
if (!addr.get().isV6LinkLocal()){
continue;
}
// Run OS-specific function to open a socket capable of receiving
// packets sent to All_DHCP_Relay_Agents_and_Servers multicast
// address.
if (openMulticastSocket(*iface, addr, port, error_handler)) {
++count;
}
}
}
// If we have open sockets, start the receiver.
if (count > 0) {
// starts the receiver thread (if queueing is enabled).
startDHCPReceiver(AF_INET6);
}
return (count > 0);
}
void
IfaceMgr::startDHCPReceiver(const uint16_t family) {
if (isDHCPReceiverRunning()) {
isc_throw(InvalidOperation, "a receiver thread already exists");
}
switch (family) {
case AF_INET:
// If the queue doesn't exist, packet queing has been configured
// as disabled. If there is no queue, we do not create a reciever.
if(!getPacketQueue4()) {
return;
}
dhcp_receiver_.reset(new WatchedThread());
dhcp_receiver_->start(std::bind(&IfaceMgr::receiveDHCP4Packets, this));
break;
case AF_INET6:
// If the queue doesn't exist, packet queing has been configured
// as disabled. If there is no queue, we do not create a reciever.
if(!getPacketQueue6()) {
return;
}
dhcp_receiver_.reset(new WatchedThread());
dhcp_receiver_->start(std::bind(&IfaceMgr::receiveDHCP6Packets, this));
break;
default:
isc_throw (BadValue, "startDHCPReceiver: invalid family: " << family);
break;
}
}
void
IfaceMgr::addInterface(const IfacePtr& iface) {
for (const IfacePtr& existing : ifaces_) {
if ((existing->getName() == iface->getName()) ||
(existing->getIndex() == iface->getIndex())) {
isc_throw(Unexpected, "Can't add " << iface->getFullName() <<
" when " << existing->getFullName() <<
" already exists.");
}
}
ifaces_.push_back(iface);
}
void
IfaceMgr::printIfaces(std::ostream& out /*= std::cout*/) {
for (IfacePtr iface : ifaces_) {
const Iface::AddressCollection& addrs = iface->getAddresses();
out << "Detected interface " << iface->getFullName()
<< ", hwtype=" << iface->getHWType()
<< ", mac=" << iface->getPlainMac();
out << ", flags=" << hex << iface->flags_ << dec << "("
<< (iface->flag_loopback_?"LOOPBACK ":"")
<< (iface->flag_up_?"UP ":"")
<< (iface->flag_running_?"RUNNING ":"")
<< (iface->flag_multicast_?"MULTICAST ":"")
<< (iface->flag_broadcast_?"BROADCAST ":"")
<< ")" << endl;
out << " " << addrs.size() << " addr(s):";
for (Iface::Address addr : addrs) {
out << " " << addr.get().toText();
}
out << endl;
}
}
IfacePtr
IfaceCollection::getIface(uint32_t ifindex) {
return (getIfaceInternal(ifindex, MultiThreadingMgr::instance().getMode()));
}
IfacePtr
IfaceCollection::getIface(const std::string& ifname) {
return (getIfaceInternal(ifname, MultiThreadingMgr::instance().getMode()));
}
IfacePtr
IfaceCollection::getIfaceInternal(uint32_t ifindex, bool need_lock) {
if (need_lock) {
lock_guard<mutex> lock(mutex_);
if (cache_ && (cache_->getIndex() == ifindex)) {
return (cache_);
}
} else {
if (cache_ && (cache_->getIndex() == ifindex)) {
return (cache_);
}
}
const auto& idx = ifaces_container_.get<1>();
auto it = idx.find(ifindex);
if (it == idx.end()) {
return (IfacePtr()); // not found
}
if (need_lock) {
lock_guard<mutex> lock(mutex_);
cache_ = *it;
return (cache_);
} else {
lock_guard<mutex> lock(mutex_);
cache_ = *it;
return (cache_);
}
}
IfacePtr
IfaceCollection::getIfaceInternal(const std::string& ifname, bool need_lock) {
if (need_lock) {
lock_guard<mutex> lock(mutex_);
if (cache_ && (cache_->getName() == ifname)) {
return (cache_);
}
} else {
if (cache_ && (cache_->getName() == ifname)) {
return (cache_);
}
}
const auto& idx = ifaces_container_.get<2>();
auto it = idx.find(ifname);
if (it == idx.end()) {
return (IfacePtr()); // not found
}
if (need_lock) {
lock_guard<mutex> lock(mutex_);
cache_ = *it;
return (cache_);
} else {
lock_guard<mutex> lock(mutex_);
cache_ = *it;
return (cache_);
}
}
IfacePtr
IfaceMgr::getIface(int ifindex) {
if ((ifindex < 0) || (ifindex > std::numeric_limits<int32_t>::max())) {
return (IfacePtr()); // out of range
}
return (ifaces_.getIface(ifindex));
}
IfacePtr
IfaceMgr::getIface(const std::string& ifname) {
if (ifname.empty()) {
return (IfacePtr()); // empty
}
return (ifaces_.getIface(ifname));
}
IfacePtr
IfaceMgr::getIface(const PktPtr& pkt) {
if (pkt->indexSet()) {
return (getIface(pkt->getIndex()));
} else {
return (getIface(pkt->getIface()));
}
}
void
IfaceMgr::clearIfaces() {
ifaces_.clear();
}
void
IfaceMgr::clearBoundAddresses() {
bound_address_.clear();
}
void
IfaceMgr::collectBoundAddresses() {
for (IfacePtr iface : ifaces_) {
for (SocketInfo sock : iface->getSockets()) {
const IOAddress& addr = sock.addr_;
if (!addr.isV4()) {
continue;
}
if (bound_address_.count(addr.toUint32()) == 0) {
bound_address_.insert(addr);
}
}
}
}
void
IfaceMgr::clearUnicasts() {
for (IfacePtr iface : ifaces_) {
iface->clearUnicasts();
}
}
int IfaceMgr::openSocket(const std::string& ifname, const IOAddress& addr,
const uint16_t port, const bool receive_bcast,
const bool send_bcast) {
IfacePtr iface = getIface(ifname);
if (!iface) {
isc_throw(BadValue, "There is no " << ifname << " interface present.");
}
if (addr.isV4()) {
return openSocket4(*iface, addr, port, receive_bcast, send_bcast);
} else if (addr.isV6()) {
return openSocket6(*iface, addr, port, receive_bcast);
} else {
isc_throw(BadValue, "Failed to detect family of address: "
<< addr);
}
}
int IfaceMgr::openSocketFromIface(const std::string& ifname,
const uint16_t port,
const uint8_t family) {
// Search for specified interface among detected interfaces.
for (IfacePtr iface : ifaces_) {
if ((iface->getFullName() != ifname) &&
(iface->getName() != ifname)) {
continue;
}
// Interface is now detected. Search for address on interface
// that matches address family (v6 or v4).
Iface::AddressCollection addrs = iface->getAddresses();
Iface::AddressCollection::iterator addr_it = addrs.begin();
while (addr_it != addrs.end()) {
if (addr_it->get().getFamily() == family) {
// We have interface and address so let's open socket.
// This may cause isc::Unexpected exception.
return (openSocket(iface->getName(), *addr_it, port, false));
}
++addr_it;
}
// If we are at the end of address collection it means that we found
// interface but there is no address for family specified.
if (addr_it == addrs.end()) {
// Stringify the family value to append it to exception string.
std::string family_name("AF_INET");
if (family == AF_INET6) {
family_name = "AF_INET6";
}
// We did not find address on the interface.
isc_throw(SocketConfigError, "There is no address for interface: "
<< ifname << ", port: " << port << ", address "
" family: " << family_name);
}
}
// If we got here it means that we had not found the specified interface.
// Otherwise we would have returned from previous exist points.
isc_throw(BadValue, "There is no " << ifname << " interface present.");
}
int IfaceMgr::openSocketFromAddress(const IOAddress& addr,
const uint16_t port) {
// Search through detected interfaces and addresses to match
// local address we got.
for (IfacePtr iface : ifaces_) {
for (Iface::Address a : iface->getAddresses()) {
// Local address must match one of the addresses
// on detected interfaces. If it does, we have
// address and interface detected so we can open
// socket.
if (a.get() == addr) {
// Open socket using local interface, address and port.
// This may cause isc::Unexpected exception.
return (openSocket(iface->getName(), a, port, false));
}
}
}
// If we got here it means that we did not find specified address
// on any available interface.
isc_throw(BadValue, "There is no such address " << addr);
}
int IfaceMgr::openSocketFromRemoteAddress(const IOAddress& remote_addr,
const uint16_t port) {
try {
// Get local address to be used to connect to remote location.
IOAddress local_address(getLocalAddress(remote_addr, port));
return openSocketFromAddress(local_address, port);
} catch (const Exception& e) {
isc_throw(SocketConfigError, e.what());
}
}
isc::asiolink::IOAddress
IfaceMgr::getLocalAddress(const IOAddress& remote_addr, const uint16_t port) {
// Create remote endpoint, we will be connecting to it.
boost::scoped_ptr<const UDPEndpoint>
remote_endpoint(static_cast<const UDPEndpoint*>
(UDPEndpoint::create(IPPROTO_UDP, remote_addr, port)));
if (!remote_endpoint) {
isc_throw(Unexpected, "Unable to create remote endpoint");
}
// Create socket that will be used to connect to remote endpoint.
boost::asio::io_service io_service;
boost::asio::ip::udp::socket sock(io_service);
boost::system::error_code err_code;
// If remote address is broadcast address we have to
// allow this on the socket.
if (remote_addr.isV4() &&
(remote_addr == IOAddress(DHCP_IPV4_BROADCAST_ADDRESS))) {
// Socket has to be open prior to setting the broadcast
// option. Otherwise set_option will complain about
// bad file descriptor.
// @todo: We don't specify interface in any way here. 255.255.255.255
// We can very easily end up with a socket working on a different
// interface.
// zero out the errno to be safe
errno = 0;
sock.open(boost::asio::ip::udp::v4(), err_code);
if (err_code) {
const char* errstr = strerror(errno);
isc_throw(Unexpected, "failed to open UDPv4 socket, reason:"
<< errstr);
}
sock.set_option(boost::asio::socket_base::broadcast(true), err_code);
if (err_code) {
sock.close();
isc_throw(Unexpected, "failed to enable broadcast on the socket");
}
}
// Try to connect to remote endpoint and check if attempt is successful.
sock.connect(remote_endpoint->getASIOEndpoint(), err_code);
if (err_code) {
sock.close();
isc_throw(Unexpected, "failed to connect to remote endpoint.");
}
// Once we are connected socket object holds local endpoint.
boost::asio::ip::udp::socket::endpoint_type local_endpoint =
sock.local_endpoint();
boost::asio::ip::address local_address(local_endpoint.address());
// Close the socket.
sock.close();
// Return address of local endpoint.
return IOAddress(local_address);
}
int
IfaceMgr::openSocket4(Iface& iface, const IOAddress& addr,
const uint16_t port, const bool receive_bcast,
const bool send_bcast) {
// Assuming that packet filter is not null, because its modifier checks it.
SocketInfo info = packet_filter_->openSocket(iface, addr, port,
receive_bcast, send_bcast);
iface.addSocket(info);
return (info.sockfd_);
}
bool
IfaceMgr::send(const Pkt6Ptr& pkt) {
IfacePtr iface = getIface(pkt);
if (!iface) {
isc_throw(BadValue, "Unable to send DHCPv6 message. Invalid interface ("
<< pkt->getIface() << ") specified.");
}
// Assuming that packet filter is not null, because its modifier checks it.
// The packet filter returns an int but in fact it either returns 0 or throws.
return (packet_filter6_->send(*iface, getSocket(pkt), pkt) == 0);
}
bool
IfaceMgr::send(const Pkt4Ptr& pkt) {
IfacePtr iface = getIface(pkt);
if (!iface) {
isc_throw(BadValue, "Unable to send DHCPv4 message. Invalid interface ("
<< pkt->getIface() << ") specified.");
}
// Assuming that packet filter is not null, because its modifier checks it.
// The packet filter returns an int but in fact it either returns 0 or throws.
return (packet_filter_->send(*iface, getSocket(pkt).sockfd_, pkt) == 0);
}
Pkt4Ptr IfaceMgr::receive4(uint32_t timeout_sec, uint32_t timeout_usec /* = 0 */) {
if (isDHCPReceiverRunning()) {
return (receive4Indirect(timeout_sec, timeout_usec));
}
return (receive4Direct(timeout_sec, timeout_usec));
}
Pkt4Ptr IfaceMgr::receive4Indirect(uint32_t timeout_sec, uint32_t timeout_usec /* = 0 */) {
// Sanity check for microsecond timeout.
if (timeout_usec >= 1000000) {
isc_throw(BadValue, "fractional timeout must be shorter than"
" one million microseconds");
}
fd_set sockets;
int maxfd = 0;
FD_ZERO(&sockets);
// if there are any callbacks for external sockets registered...
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
if (!callbacks_.empty()) {
for (SocketCallbackInfo s : callbacks_) {
// Add this socket to listening set
addFDtoSet(s.socket_, maxfd, &sockets);
}
}
}
// Add Receiver ready watch socket
addFDtoSet(dhcp_receiver_->getWatchFd(WatchedThread::READY), maxfd, &sockets);
// Add Receiver error watch socket
addFDtoSet(dhcp_receiver_->getWatchFd(WatchedThread::ERROR), maxfd, &sockets);
// Set timeout for our next select() call. If there are
// no DHCP packets to read, then we'll wait for a finite
// amount of time for an IO event. Otherwise, we'll
// poll (timeout = 0 secs). We need to poll, even if
// DHCP packets are waiting so we don't starve external
// sockets under heavy DHCP load.
struct timeval select_timeout;
if (getPacketQueue4()->empty()) {
select_timeout.tv_sec = timeout_sec;
select_timeout.tv_usec = timeout_usec;
} else {
select_timeout.tv_sec = 0;
select_timeout.tv_usec = 0;
}
// zero out the errno to be safe
errno = 0;
int result = select(maxfd + 1, &sockets, 0, 0, &select_timeout);
if ((result == 0) && getPacketQueue4()->empty()) {
// nothing received and timeout has been reached
return (Pkt4Ptr());
} else if (result < 0) {
// In most cases we would like to know whether select() returned
// an error because of a signal being received or for some other
// reason. This is because DHCP servers use signals to trigger
// certain actions, like reconfiguration or graceful shutdown.
// By catching a dedicated exception the caller will know if the
// error returned by the function is due to the reception of the
// signal or for some other reason.
if (errno == EINTR) {
isc_throw(SignalInterruptOnSelect, strerror(errno));
} else if (errno == EBADF) {
int cnt = purgeBadSockets();
isc_throw(SocketReadError,
"SELECT interrupted by one invalid sockets, purged "
<< cnt << " socket descriptors");
} else {
isc_throw(SocketReadError, strerror(errno));
}
}
// We only check external sockets if select detected an event.
if (result > 0) {
// Check for receiver thread read errors.
if (dhcp_receiver_->isReady(WatchedThread::ERROR)) {
string msg = dhcp_receiver_->getLastError();
dhcp_receiver_->clearReady(WatchedThread::ERROR);
isc_throw(SocketReadError, msg);
}
// Let's find out which external socket has the data
SocketCallbackInfo ex_sock;
bool found = false;
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
for (SocketCallbackInfo s : callbacks_) {
if (!FD_ISSET(s.socket_, &sockets)) {
continue;
}
found = true;
// something received over external socket
if (s.callback_) {
// Note the external socket to call its callback without
// the lock taken so it can be deleted.
ex_sock = s;
break;
}
}
}
if (ex_sock.callback_) {
// Calling the external socket's callback provides its service
// layer access without integrating any specific features
// in IfaceMgr
ex_sock.callback_(ex_sock.socket_);
}
if (found) {
return (Pkt4Ptr());
}
}
// If we're here it should only be because there are DHCP packets waiting.
Pkt4Ptr pkt = getPacketQueue4()->dequeuePacket();
if (!pkt) {
dhcp_receiver_->clearReady(WatchedThread::READY);
}
return (pkt);
}
Pkt4Ptr IfaceMgr::receive4Direct(uint32_t timeout_sec, uint32_t timeout_usec /* = 0 */) {
// Sanity check for microsecond timeout.
if (timeout_usec >= 1000000) {
isc_throw(BadValue, "fractional timeout must be shorter than"
" one million microseconds");
}
boost::scoped_ptr<SocketInfo> candidate;
fd_set sockets;
int maxfd = 0;
FD_ZERO(&sockets);
/// @todo: marginal performance optimization. We could create the set once
/// and then use its copy for select(). Please note that select() modifies
/// provided set to indicated which sockets have something to read.
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
// Only deal with IPv4 addresses.
if (s.addr_.isV4()) {
// Add this socket to listening set
addFDtoSet(s.sockfd_, maxfd, &sockets);
}
}
}
// if there are any callbacks for external sockets registered...
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
if (!callbacks_.empty()) {
for (SocketCallbackInfo s : callbacks_) {
// Add this socket to listening set
addFDtoSet(s.socket_, maxfd, &sockets);
}
}
}
struct timeval select_timeout;
select_timeout.tv_sec = timeout_sec;
select_timeout.tv_usec = timeout_usec;
// zero out the errno to be safe
errno = 0;
int result = select(maxfd + 1, &sockets, 0, 0, &select_timeout);
if (result == 0) {
// nothing received and timeout has been reached
return (Pkt4Ptr()); // null
} else if (result < 0) {
// In most cases we would like to know whether select() returned
// an error because of a signal being received or for some other
// reason. This is because DHCP servers use signals to trigger
// certain actions, like reconfiguration or graceful shutdown.
// By catching a dedicated exception the caller will know if the
// error returned by the function is due to the reception of the
// signal or for some other reason.
if (errno == EINTR) {
isc_throw(SignalInterruptOnSelect, strerror(errno));
} else if (errno == EBADF) {
int cnt = purgeBadSockets();
isc_throw(SocketReadError,
"SELECT interrupted by one invalid sockets, purged "
<< cnt << " socket descriptors");
} else {
isc_throw(SocketReadError, strerror(errno));
}
}
// Let's find out which socket has the data
SocketCallbackInfo ex_sock;
bool found = false;
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
for (SocketCallbackInfo s : callbacks_) {
if (!FD_ISSET(s.socket_, &sockets)) {
continue;
}
found = true;
// something received over external socket
if (s.callback_) {
// Note the external socket to call its callback without
// the lock taken so it can be deleted.
ex_sock = s;
break;
}
}
}
if (ex_sock.callback_) {
// Calling the external socket's callback provides its service
// layer access without integrating any specific features
// in IfaceMgr
ex_sock.callback_(ex_sock.socket_);
}
if (found) {
return (Pkt4Ptr());
}
// Let's find out which interface/socket has the data
IfacePtr recv_if;
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
if (FD_ISSET(s.sockfd_, &sockets)) {
candidate.reset(new SocketInfo(s));
break;
}
}
if (candidate) {
recv_if = iface;
break;
}
}
if (!candidate || !recv_if) {
isc_throw(SocketReadError, "received data over unknown socket");
}
// Now we have a socket, let's get some data from it!
// Assuming that packet filter is not null, because its modifier checks it.
return (packet_filter_->receive(*recv_if, *candidate));
}
Pkt6Ptr
IfaceMgr::receive6(uint32_t timeout_sec, uint32_t timeout_usec /* = 0 */) {
if (isDHCPReceiverRunning()) {
return (receive6Indirect(timeout_sec, timeout_usec));
}
return (receive6Direct(timeout_sec, timeout_usec));
}
void
IfaceMgr::addFDtoSet(int fd, int& maxfd, fd_set* sockets) {
if (!sockets) {
isc_throw(BadValue, "addFDtoSet: sockets can't be null");
}
FD_SET(fd, sockets);
if (maxfd < fd) {
maxfd = fd;
}
}
Pkt6Ptr
IfaceMgr::receive6Direct(uint32_t timeout_sec, uint32_t timeout_usec /* = 0 */ ) {
// Sanity check for microsecond timeout.
if (timeout_usec >= 1000000) {
isc_throw(BadValue, "fractional timeout must be shorter than"
" one million microseconds");
}
boost::scoped_ptr<SocketInfo> candidate;
fd_set sockets;
int maxfd = 0;
FD_ZERO(&sockets);
/// @todo: marginal performance optimization. We could create the set once
/// and then use its copy for select(). Please note that select() modifies
/// provided set to indicated which sockets have something to read.
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
// Only deal with IPv6 addresses.
if (s.addr_.isV6()) {
// Add this socket to listening set
addFDtoSet(s.sockfd_, maxfd, &sockets);
}
}
}
// if there are any callbacks for external sockets registered...
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
if (!callbacks_.empty()) {
for (SocketCallbackInfo s : callbacks_) {
// Add this socket to listening set
addFDtoSet(s.socket_, maxfd, &sockets);
}
}
}
struct timeval select_timeout;
select_timeout.tv_sec = timeout_sec;
select_timeout.tv_usec = timeout_usec;
// zero out the errno to be safe
errno = 0;
int result = select(maxfd + 1, &sockets, 0, 0, &select_timeout);
if (result == 0) {
// nothing received and timeout has been reached
return (Pkt6Ptr()); // null
} else if (result < 0) {
// In most cases we would like to know whether select() returned
// an error because of a signal being received or for some other
// reason. This is because DHCP servers use signals to trigger
// certain actions, like reconfiguration or graceful shutdown.
// By catching a dedicated exception the caller will know if the
// error returned by the function is due to the reception of the
// signal or for some other reason.
if (errno == EINTR) {
isc_throw(SignalInterruptOnSelect, strerror(errno));
} else if (errno == EBADF) {
int cnt = purgeBadSockets();
isc_throw(SocketReadError,
"SELECT interrupted by one invalid sockets, purged "
<< cnt << " socket descriptors");
} else {
isc_throw(SocketReadError, strerror(errno));
}
}
// Let's find out which socket has the data
SocketCallbackInfo ex_sock;
bool found = false;
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
for (SocketCallbackInfo s : callbacks_) {
if (!FD_ISSET(s.socket_, &sockets)) {
continue;
}
found = true;
// something received over external socket
if (s.callback_) {
// Note the external socket to call its callback without
// the lock taken so it can be deleted.
ex_sock = s;
break;
}
}
}
if (ex_sock.callback_) {
// Calling the external socket's callback provides its service
// layer access without integrating any specific features
// in IfaceMgr
ex_sock.callback_(ex_sock.socket_);
}
if (found) {
return (Pkt6Ptr());
}
// Let's find out which interface/socket has the data
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
if (FD_ISSET(s.sockfd_, &sockets)) {
candidate.reset(new SocketInfo(s));
break;
}
}
if (candidate) {
break;
}
}
if (!candidate) {
isc_throw(SocketReadError, "received data over unknown socket");
}
// Assuming that packet filter is not null, because its modifier checks it.
return (packet_filter6_->receive(*candidate));
}
Pkt6Ptr
IfaceMgr::receive6Indirect(uint32_t timeout_sec, uint32_t timeout_usec /* = 0 */ ) {
// Sanity check for microsecond timeout.
if (timeout_usec >= 1000000) {
isc_throw(BadValue, "fractional timeout must be shorter than"
" one million microseconds");
}
fd_set sockets;
int maxfd = 0;
FD_ZERO(&sockets);
// if there are any callbacks for external sockets registered...
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
if (!callbacks_.empty()) {
for (SocketCallbackInfo s : callbacks_) {
// Add this socket to listening set
addFDtoSet(s.socket_, maxfd, &sockets);
}
}
}
// Add Receiver ready watch socket
addFDtoSet(dhcp_receiver_->getWatchFd(WatchedThread::READY), maxfd, &sockets);
// Add Receiver error watch socket
addFDtoSet(dhcp_receiver_->getWatchFd(WatchedThread::ERROR), maxfd, &sockets);
// Set timeout for our next select() call. If there are
// no DHCP packets to read, then we'll wait for a finite
// amount of time for an IO event. Otherwise, we'll
// poll (timeout = 0 secs). We need to poll, even if
// DHCP packets are waiting so we don't starve external
// sockets under heavy DHCP load.
struct timeval select_timeout;
if (getPacketQueue6()->empty()) {
select_timeout.tv_sec = timeout_sec;
select_timeout.tv_usec = timeout_usec;
} else {
select_timeout.tv_sec = 0;
select_timeout.tv_usec = 0;
}
// zero out the errno to be safe
errno = 0;
int result = select(maxfd + 1, &sockets, 0, 0, &select_timeout);
if ((result == 0) && getPacketQueue6()->empty()) {
// nothing received and timeout has been reached
return (Pkt6Ptr());
} else if (result < 0) {
// In most cases we would like to know whether select() returned
// an error because of a signal being received or for some other
// reason. This is because DHCP servers use signals to trigger
// certain actions, like reconfiguration or graceful shutdown.
// By catching a dedicated exception the caller will know if the
// error returned by the function is due to the reception of the
// signal or for some other reason.
if (errno == EINTR) {
isc_throw(SignalInterruptOnSelect, strerror(errno));
} else if (errno == EBADF) {
int cnt = purgeBadSockets();
isc_throw(SocketReadError,
"SELECT interrupted by one invalid sockets, purged "
<< cnt << " socket descriptors");
} else {
isc_throw(SocketReadError, strerror(errno));
}
}
// We only check external sockets if select detected an event.
if (result > 0) {
// Check for receiver thread read errors.
if (dhcp_receiver_->isReady(WatchedThread::ERROR)) {
string msg = dhcp_receiver_->getLastError();
dhcp_receiver_->clearReady(WatchedThread::ERROR);
isc_throw(SocketReadError, msg);
}
// Let's find out which external socket has the data
SocketCallbackInfo ex_sock;
bool found = false;
{
std::lock_guard<std::mutex> lock(callbacks_mutex_);
for (SocketCallbackInfo s : callbacks_) {
if (!FD_ISSET(s.socket_, &sockets)) {
continue;
}
found = true;
// something received over external socket
if (s.callback_) {
// Note the external socket to call its callback without
// the lock taken so it can be deleted.
ex_sock = s;
break;
}
}
}
if (ex_sock.callback_) {
// Calling the external socket's callback provides its service
// layer access without integrating any specific features
// in IfaceMgr
ex_sock.callback_(ex_sock.socket_);
}
if (found) {
return (Pkt6Ptr());
}
}
// If we're here it should only be because there are DHCP packets waiting.
Pkt6Ptr pkt = getPacketQueue6()->dequeuePacket();
if (!pkt) {
dhcp_receiver_->clearReady(WatchedThread::READY);
}
return (pkt);
}
void
IfaceMgr::receiveDHCP4Packets() {
fd_set sockets;
int maxfd = 0;
FD_ZERO(&sockets);
// Add terminate watch socket.
addFDtoSet(dhcp_receiver_->getWatchFd(WatchedThread::TERMINATE), maxfd, &sockets);
// Add Interface sockets.
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
// Only deal with IPv4 addresses.
if (s.addr_.isV4()) {
// Add this socket to listening set.
addFDtoSet(s.sockfd_, maxfd, &sockets);
}
}
}
for (;;) {
// Check the watch socket.
if (dhcp_receiver_->shouldTerminate()) {
return;
}
fd_set rd_set;
FD_COPY(&sockets, &rd_set);
// zero out the errno to be safe.
errno = 0;
// Select with null timeouts to wait indefinetly an event
int result = select(maxfd + 1, &rd_set, 0, 0, 0);
// Re-check the watch socket.
if (dhcp_receiver_->shouldTerminate()) {
return;
}
if (result == 0) {
// nothing received?
continue;
} else if (result < 0) {
// This thread should not get signals?
if (errno != EINTR) {
// Signal the error to receive4.
dhcp_receiver_->setError(strerror(errno));
// We need to sleep in case of the error condition to
// prevent the thread from tight looping when result
// gets negative.
sleep(1);
}
continue;
}
// Let's find out which interface/socket has data.
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
if (FD_ISSET(s.sockfd_, &sockets)) {
receiveDHCP4Packet(*iface, s);
// Can take time so check one more time the watch socket.
if (dhcp_receiver_->shouldTerminate()) {
return;
}
}
}
}
}
}
void
IfaceMgr::receiveDHCP6Packets() {
fd_set sockets;
int maxfd = 0;
FD_ZERO(&sockets);
// Add terminate watch socket.
addFDtoSet(dhcp_receiver_->getWatchFd(WatchedThread::TERMINATE), maxfd, &sockets);
// Add Interface sockets.
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
// Only deal with IPv6 addresses.
if (s.addr_.isV6()) {
// Add this socket to listening set.
addFDtoSet(s.sockfd_ , maxfd, &sockets);
}
}
}
for (;;) {
// Check the watch socket.
if (dhcp_receiver_->shouldTerminate()) {
return;
}
fd_set rd_set;
FD_COPY(&sockets, &rd_set);
// zero out the errno to be safe.
errno = 0;
// Note we wait until something happen.
int result = select(maxfd + 1, &rd_set, 0, 0, 0);
// Re-check the watch socket.
if (dhcp_receiver_->shouldTerminate()) {
return;
}
if (result == 0) {
// nothing received?
continue;
} else if (result < 0) {
// This thread should not get signals?
if (errno != EINTR) {
// Signal the error to receive6.
dhcp_receiver_->setError(strerror(errno));
// We need to sleep in case of the error condition to
// prevent the thread from tight looping when result
// gets negative.
sleep(1);
}
continue;
}
// Let's find out which interface/socket has data.
for (IfacePtr iface : ifaces_) {
for (SocketInfo s : iface->getSockets()) {
if (FD_ISSET(s.sockfd_, &sockets)) {
receiveDHCP6Packet(s);
// Can take time so check one more time the watch socket.
if (dhcp_receiver_->shouldTerminate()) {
return;
}
}
}
}
}
}
void
IfaceMgr::receiveDHCP4Packet(Iface& iface, const SocketInfo& socket_info) {
int len;
int result = ioctl(socket_info.sockfd_, FIONREAD, &len);
if (result < 0) {
// Signal the error to receive4.
dhcp_receiver_->setError(strerror(errno));
return;
}
if (len == 0) {
// Nothing to read.
return;
}
Pkt4Ptr pkt;
try {
pkt = packet_filter_->receive(iface, socket_info);
} catch (const std::exception& ex) {
dhcp_receiver_->setError(strerror(errno));
} catch (...) {
dhcp_receiver_->setError("packet filter receive() failed");
}
if (pkt) {
getPacketQueue4()->enqueuePacket(pkt, socket_info);
dhcp_receiver_->markReady(WatchedThread::READY);
}
}
void
IfaceMgr::receiveDHCP6Packet(const SocketInfo& socket_info) {
int len;
int result = ioctl(socket_info.sockfd_, FIONREAD, &len);
if (result < 0) {
// Signal the error to receive6.
dhcp_receiver_->setError(strerror(errno));
return;
}
if (len == 0) {
// Nothing to read.
return;
}
Pkt6Ptr pkt;
try {
pkt = packet_filter6_->receive(socket_info);
} catch (const std::exception& ex) {
dhcp_receiver_->setError(ex.what());
} catch (...) {
dhcp_receiver_->setError("packet filter receive() failed");
}
if (pkt) {
getPacketQueue6()->enqueuePacket(pkt, socket_info);
dhcp_receiver_->markReady(WatchedThread::READY);
}
}
uint16_t
IfaceMgr::getSocket(const isc::dhcp::Pkt6Ptr& pkt) {
IfacePtr iface = getIface(pkt);
if (!iface) {
isc_throw(IfaceNotFound, "Tried to find socket for non-existent interface");
}
const Iface::SocketCollection& socket_collection = iface->getSockets();
Iface::SocketCollection::const_iterator candidate = socket_collection.end();
Iface::SocketCollection::const_iterator s;
for (s = socket_collection.begin(); s != socket_collection.end(); ++s) {
// We should not merge those conditions for debugging reasons.
// V4 sockets are useless for sending v6 packets.
if (s->family_ != AF_INET6) {
continue;
}
// Sockets bound to multicast address are useless for sending anything.
if (s->addr_.isV6Multicast()) {
continue;
}
if (s->addr_ == pkt->getLocalAddr()) {
// This socket is bound to the source address. This is perfect
// match, no need to look any further.
return (s->sockfd_);
}
// If we don't have any other candidate, this one will do
if (candidate == socket_collection.end()) {
candidate = s;
} else {
// If we want to send something to link-local and the socket is
// bound to link-local or we want to send to global and the socket
// is bound to global, then use it as candidate
if ( (pkt->getRemoteAddr().isV6LinkLocal() &&
s->addr_.isV6LinkLocal()) ||
(!pkt->getRemoteAddr().isV6LinkLocal() &&
!s->addr_.isV6LinkLocal()) ) {
candidate = s;
}
}
}
if (candidate != socket_collection.end()) {
return (candidate->sockfd_);
}
isc_throw(SocketNotFound, "Interface " << iface->getFullName()
<< " does not have any suitable IPv6 sockets open.");
}
SocketInfo
IfaceMgr::getSocket(const isc::dhcp::Pkt4Ptr& pkt) {
IfacePtr iface = getIface(pkt);
if (!iface) {
isc_throw(IfaceNotFound, "Tried to find socket for non-existent interface");
}
const Iface::SocketCollection& socket_collection = iface->getSockets();
// A candidate being an end of the iterator marks that it is a beginning of
// the socket search and that the candidate needs to be set to the first
// socket found.
Iface::SocketCollection::const_iterator candidate = socket_collection.end();
Iface::SocketCollection::const_iterator s;
for (s = socket_collection.begin(); s != socket_collection.end(); ++s) {
if (s->family_ == AF_INET) {
if (s->addr_ == pkt->getLocalAddr()) {
return (*s);
}
if (candidate == socket_collection.end()) {
candidate = s;
}
}
}
if (candidate == socket_collection.end()) {
isc_throw(SocketNotFound, "Interface " << iface->getFullName()
<< " does not have any suitable IPv4 sockets open.");
}
return (*candidate);
}
bool
IfaceMgr::configureDHCPPacketQueue(uint16_t family, data::ConstElementPtr queue_control) {
if (isDHCPReceiverRunning()) {
isc_throw(InvalidOperation, "Cannot reconfigure queueing"
" while DHCP receiver thread is running");
}
bool enable_queue = false;
if (queue_control) {
try {
enable_queue = data::SimpleParser::getBoolean(queue_control, "enable-queue");
} catch (...) {
// @todo - for now swallow not found errors.
// if not present we assume default
}
}
if (enable_queue) {
// Try to create the queue as configured.
if (family == AF_INET) {
packet_queue_mgr4_->createPacketQueue(queue_control);
} else {
packet_queue_mgr6_->createPacketQueue(queue_control);
}
} else {
// Destroy the current queue (if one), this inherently disables threading.
if (family == AF_INET) {
packet_queue_mgr4_->destroyPacketQueue();
} else {
packet_queue_mgr6_->destroyPacketQueue();
}
}
return(enable_queue);
}
} // end of namespace isc::dhcp
} // end of namespace isc
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