/*
* Copyright (c)2013-2020 ZeroTier, Inc.
*
* Use of this software is governed by the Business Source License included
* in the LICENSE.TXT file in the project's root directory.
*
* Change Date: 2025-01-01
*
* On the date above, in accordance with the Business Source License, use
* of this software will be governed by version 2.0 of the Apache License.
*/
/****/
#ifndef ZT_MULTICASTGROUP_HPP
#define ZT_MULTICASTGROUP_HPP
#include "Constants.hpp"
#include "MAC.hpp"
#include "InetAddress.hpp"
#include "Utils.hpp"
#include "TriviallyCopyable.hpp"
namespace ZeroTier {
/**
* A multicast group composed of a multicast MAC and a 32-bit ADI field
*
* ADI stands for additional distinguishing information. ADI is primarily for
* adding additional information to broadcast (ff:ff:ff:ff:ff:ff) memberships,
* since straight-up broadcast won't scale. Right now it's zero except for
* IPv4 ARP, where it holds the IPv4 address itself to make ARP into a
* selective multicast query that can scale.
*
* In the future we might add some kind of plugin architecture that can add
* ADI for things like mDNS (multicast DNS) to improve the selectivity of
* those protocols.
*
* MulticastGroup behaves as an immutable value object.
*/
class MulticastGroup : public TriviallyCopyable
{
public:
ZT_INLINE MulticastGroup() noexcept : m_mac(), m_adi(0) {}
ZT_INLINE MulticastGroup(const MAC &m,uint32_t a) noexcept : m_mac(m), m_adi(a) {}
/**
* Derive the multicast group used for address resolution (ARP/NDP) for an IP
*
* @param ip IP address (port field is ignored)
* @return Multicast group for ARP/NDP
*/
static ZT_INLINE MulticastGroup deriveMulticastGroupForAddressResolution(const InetAddress &ip) noexcept
{
if (ip.isV4()) {
// IPv4 wants broadcast MACs, so we shove the V4 address itself into
// the Multicast Group ADI field. Making V4 ARP work is basically why
// ADI was added, as well as handling other things that want mindless
// Ethernet broadcast to all.
return MulticastGroup(MAC(0xffffffffffffULL),Utils::ntoh(*((const uint32_t *)ip.rawIpData())));
} else if (ip.isV6()) {
// IPv6 is better designed in this respect. We can compute the IPv6
// multicast address directly from the IP address, and it gives us
// 24 bits of uniqueness. Collisions aren't likely to be common enough
// to care about.
const uint8_t *const a = reinterpret_cast<const uint8_t *>(ip.rawIpData()); // NOLINT(hicpp-use-auto,modernize-use-auto)
return MulticastGroup(MAC(0x33,0x33,0xff,a[13],a[14],a[15]),0);
}
return MulticastGroup(); // NOLINT(modernize-return-braced-init-list)
}
/**
* @return Ethernet MAC portion of multicast group
*/
ZT_INLINE const MAC &mac() const noexcept { return m_mac; }
/**
* @return Additional distinguishing information, which is normally zero except for IPv4 ARP where it's the IPv4 address
*/
ZT_INLINE uint32_t adi() const { return m_adi; }
ZT_INLINE bool operator==(const MulticastGroup &g) const noexcept { return ((m_mac == g.m_mac) && (m_adi == g.m_adi)); }
ZT_INLINE bool operator!=(const MulticastGroup &g) const noexcept { return ((m_mac != g.m_mac) || (m_adi != g.m_adi)); }
ZT_INLINE bool operator<(const MulticastGroup &g) const noexcept
{
if (m_mac < g.m_mac)
return true;
else if (m_mac == g.m_mac)
return (m_adi < g.m_adi);
return false;
}
ZT_INLINE bool operator>(const MulticastGroup &g) const noexcept { return (g < *this); }
ZT_INLINE bool operator<=(const MulticastGroup &g) const noexcept { return !(g < *this); }
ZT_INLINE bool operator>=(const MulticastGroup &g) const noexcept { return !(*this < g); }
ZT_INLINE unsigned long hashCode() const noexcept { return (m_mac.hashCode() + (unsigned long)m_adi); }
private:
MAC m_mac;
uint32_t m_adi;
};
} // namespace ZeroTier
#endif