/* * ZeroTier One - Network Virtualization Everywhere * Copyright (C) 2011-2015 ZeroTier, Inc. * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * -- * * ZeroTier may be used and distributed under the terms of the GPLv3, which * are available at: http://www.gnu.org/licenses/gpl-3.0.html * * If you would like to embed ZeroTier into a commercial application or * redistribute it in a modified binary form, please contact ZeroTier Networks * LLC. Start here: http://www.zerotier.com/ */ #ifndef ZT_N_PACKET_HPP #define ZT_N_PACKET_HPP #include #include #include #include #include #include "Constants.hpp" #include "Address.hpp" #include "Poly1305.hpp" #include "Salsa20.hpp" #include "Utils.hpp" #include "Buffer.hpp" #include "../ext/lz4/lz4.h" /** * Protocol version -- incremented only for MAJOR changes * * 1 - 0.2.0 ... 0.2.5 * 2 - 0.3.0 ... 0.4.5 * * Added signature and originating peer to multicast frame * * Double size of multicast frame bloom filter * 3 - 0.5.0 ... 0.6.0 * * Yet another multicast redesign * * New crypto completely changes key agreement cipher * 4 - 0.6.0 ... CURRENT * * New identity format based on hashcash design * * This isn't going to change again for a long time unless your * author wakes up again at 4am with another great idea. :P */ #define ZT_PROTO_VERSION 4 /** * Minimum supported protocol version */ #define ZT_PROTO_VERSION_MIN 4 /** * Maximum hop count allowed by packet structure (3 bits, 0-7) * * This is a protocol constant. It's the maximum allowed by the length * of the hop counter -- three bits. See node/Constants.hpp for the * pragmatic forwarding limit, which is typically lower. */ #define ZT_PROTO_MAX_HOPS 7 /** * Cipher suite: Curve25519/Poly1305/Salsa20/12/NOCRYPT * * This specifies Poly1305 MAC using a 32-bit key derived from the first * 32 bytes of a Salsa20/12 keystream as in the Salsa20/12 cipher suite, * but the payload is not encrypted. This is currently only used to send * HELLO since that's the public key specification packet and must be * sent in the clear. Key agreement is performed using Curve25519 elliptic * curve Diffie-Hellman. */ #define ZT_PROTO_CIPHER_SUITE__C25519_POLY1305_NONE 0 /** * Cipher suite: Curve25519/Poly1305/Salsa20/12 * * This specifies Poly1305 using the first 32 bytes of a Salsa20/12 key * stream as its one-time-use key followed by payload encryption with * the remaining Salsa20/12 key stream. Key agreement is performed using * Curve25519 elliptic curve Diffie-Hellman. */ #define ZT_PROTO_CIPHER_SUITE__C25519_POLY1305_SALSA2012 1 /** * Cipher suite: PFS negotiated ephemeral cipher suite and authentication * * This message is encrypted with the latest negotiated ephemeral (PFS) * key pair and cipher suite. If authentication fails, VERB_SET_EPHEMERAL_KEY * may be sent to renegotiate ephemeral keys. */ #define ZT_PROTO_CIPHER_SUITE__EPHEMERAL 7 /** * DEPRECATED payload encrypted flag, will be removed for re-use soon. * * This has been replaced by the two-bit cipher suite selection field where * a value of 0 indicates unencrypted (but authenticated) messages. */ #define ZT_PROTO_FLAG_ENCRYPTED 0x80 /** * Header flag indicating that a packet is fragmented * * If this flag is set, the receiver knows to expect more than one fragment. * See Packet::Fragment for details. */ #define ZT_PROTO_FLAG_FRAGMENTED 0x40 /** * Verb flag indicating payload is compressed with LZ4 */ #define ZT_PROTO_VERB_FLAG_COMPRESSED 0x80 /** * Rounds used for Salsa20 encryption in ZT * * Discussion: * * DJB (Salsa20's designer) designed Salsa20 with a significant margin of 20 * rounds, but has said repeatedly that 12 is likely sufficient. So far (as of * July 2015) there are no published attacks against 12 rounds, let alone 20. * * In cryptography, a "break" means something different from what it means in * common discussion. If a cipher is 256 bits strong and someone finds a way * to reduce key search to 254 bits, this constitues a "break" in the academic * literature. 254 bits is still far beyond what can be leveraged to accomplish * a "break" as most people would understand it -- the actual decryption and * reading of traffic. * * Nevertheless, "attacks only get better" as cryptographers like to say. As * a result, they recommend not using anything that's shown any weakness even * if that weakness is so far only meaningful to academics. It may be a sign * of a deeper problem. * * So why choose a lower round count? * * Turns out the speed difference is nontrivial. On a Macbook Pro (Core i3) 20 * rounds of SSE-optimized Salsa20 achieves ~508mb/sec/core, while 12 rounds * hits ~832mb/sec/core. ZeroTier is designed for multiple objectives: * security, simplicity, and performance. In this case a deference was made * for performance. * * Meta discussion: * * The cipher is not the thing you should be paranoid about. * * I'll qualify that. If the cipher is known to be weak, like RC4, or has a * key size that is too small, like DES, then yes you should worry about * the cipher. * * But if the cipher is strong and your adversary is anyone other than the * intelligence apparatus of a major superpower, you are fine in that * department. * * Go ahead. Search for the last ten vulnerabilities discovered in SSL. Not * a single one involved the breaking of a cipher. Now broaden your search. * Look for issues with SSH, IPSec, etc. The only cipher-related issues you * will find might involve the use of RC4 or MD5, algorithms with known * issues or small key/digest sizes. But even weak ciphers are difficult to * exploit in the real world -- you usually need a lot of data and a lot of * compute time. No, virtually EVERY security vulnerability you will find * involves a problem with the IMPLEMENTATION not with the cipher. * * A flaw in ZeroTier's protocol or code is incredibly, unbelievably * more likely than a flaw in Salsa20 or any other cipher or cryptographic * primitive it uses. We're talking odds of dying in a car wreck vs. odds of * being personally impacted on the head by a meteorite. Nobody without a * billion dollar budget is going to break into your network by actually * cracking Salsa20/12 (or even /8) in the field. * * So stop worrying about the cipher unless you are, say, the Kremlin and your * adversary is the NSA and the GCHQ. In that case... well that's above my * pay grade. I'll just say defense in depth. */ #define ZT_PROTO_SALSA20_ROUNDS 12 // Field indexes in packet header #define ZT_PACKET_IDX_IV 0 #define ZT_PACKET_IDX_DEST 8 #define ZT_PACKET_IDX_SOURCE 13 #define ZT_PACKET_IDX_FLAGS 18 #define ZT_PACKET_IDX_MAC 19 #define ZT_PACKET_IDX_VERB 27 #define ZT_PACKET_IDX_PAYLOAD 28 /** * Packet buffer size (can be changed) * * The current value is big enough for ZT_MAX_PACKET_FRAGMENTS, the pragmatic * packet fragment limit, times the default UDP MTU. Most packets won't be * this big. */ #define ZT_PROTO_MAX_PACKET_LENGTH (ZT_MAX_PACKET_FRAGMENTS * ZT_UDP_DEFAULT_PAYLOAD_MTU) /** * Minimum viable packet length (a.k.a. header length) */ #define ZT_PROTO_MIN_PACKET_LENGTH ZT_PACKET_IDX_PAYLOAD // Indexes of fields in fragment header #define ZT_PACKET_FRAGMENT_IDX_PACKET_ID 0 #define ZT_PACKET_FRAGMENT_IDX_DEST 8 #define ZT_PACKET_FRAGMENT_IDX_FRAGMENT_INDICATOR 13 #define ZT_PACKET_FRAGMENT_IDX_FRAGMENT_NO 14 #define ZT_PACKET_FRAGMENT_IDX_HOPS 15 #define ZT_PACKET_FRAGMENT_IDX_PAYLOAD 16 /** * Magic number found at ZT_PACKET_FRAGMENT_IDX_FRAGMENT_INDICATOR */ #define ZT_PACKET_FRAGMENT_INDICATOR ZT_ADDRESS_RESERVED_PREFIX /** * Minimum viable fragment length */ #define ZT_PROTO_MIN_FRAGMENT_LENGTH ZT_PACKET_FRAGMENT_IDX_PAYLOAD // Destination address types from HELLO, OK(HELLO), and other message types #define ZT_PROTO_DEST_ADDRESS_TYPE_NONE 0 #define ZT_PROTO_DEST_ADDRESS_TYPE_ZEROTIER 1 // reserved but unused #define ZT_PROTO_DEST_ADDRESS_TYPE_ETHERNET 2 // future use #define ZT_PROTO_DEST_ADDRESS_TYPE_BLUETOOTH 3 // future use #define ZT_PROTO_DEST_ADDRESS_TYPE_IPV4 4 #define ZT_PROTO_DEST_ADDRESS_TYPE_LTE_DIRECT 5 // future use #define ZT_PROTO_DEST_ADDRESS_TYPE_IPV6 6 // Ephemeral key record flags #define ZT_PROTO_EPHEMERAL_KEY_FLAG_FIPS 0x01 // future use // Ephemeral key record symmetric cipher types #define ZT_PROTO_EPHEMERAL_KEY_SYMMETRIC_CIPHER_SALSA2012_POLY1305 0x01 #define ZT_PROTO_EPHEMERAL_KEY_SYMMETRIC_CIPHER_AES256_GCM 0x02 // Ephemeral key record public key types #define ZT_PROTO_EPHEMERAL_KEY_PK_C25519 0x01 #define ZT_PROTO_EPHEMERAL_KEY_PK_NISTP256 0x02 // Field incides for parsing verbs ------------------------------------------- // Some verbs have variable-length fields. Those aren't fully defined here // yet-- instead they are parsed using relative indexes in IncomingPacket. // See their respective handler functions. #define ZT_PROTO_VERB_HELLO_IDX_PROTOCOL_VERSION (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_HELLO_IDX_MAJOR_VERSION (ZT_PROTO_VERB_HELLO_IDX_PROTOCOL_VERSION + 1) #define ZT_PROTO_VERB_HELLO_IDX_MINOR_VERSION (ZT_PROTO_VERB_HELLO_IDX_MAJOR_VERSION + 1) #define ZT_PROTO_VERB_HELLO_IDX_REVISION (ZT_PROTO_VERB_HELLO_IDX_MINOR_VERSION + 1) #define ZT_PROTO_VERB_HELLO_IDX_TIMESTAMP (ZT_PROTO_VERB_HELLO_IDX_REVISION + 2) #define ZT_PROTO_VERB_HELLO_IDX_IDENTITY (ZT_PROTO_VERB_HELLO_IDX_TIMESTAMP + 8) #define ZT_PROTO_VERB_ERROR_IDX_IN_RE_VERB (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_ERROR_IDX_IN_RE_PACKET_ID (ZT_PROTO_VERB_ERROR_IDX_IN_RE_VERB + 1) #define ZT_PROTO_VERB_ERROR_IDX_ERROR_CODE (ZT_PROTO_VERB_ERROR_IDX_IN_RE_PACKET_ID + 8) #define ZT_PROTO_VERB_ERROR_IDX_PAYLOAD (ZT_PROTO_VERB_ERROR_IDX_ERROR_CODE + 1) #define ZT_PROTO_VERB_OK_IDX_IN_RE_VERB (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_OK_IDX_IN_RE_PACKET_ID (ZT_PROTO_VERB_OK_IDX_IN_RE_VERB + 1) #define ZT_PROTO_VERB_OK_IDX_PAYLOAD (ZT_PROTO_VERB_OK_IDX_IN_RE_PACKET_ID + 8) #define ZT_PROTO_VERB_WHOIS_IDX_ZTADDRESS (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_RENDEZVOUS_IDX_FLAGS (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_RENDEZVOUS_IDX_ZTADDRESS (ZT_PROTO_VERB_RENDEZVOUS_IDX_FLAGS + 1) #define ZT_PROTO_VERB_RENDEZVOUS_IDX_PORT (ZT_PROTO_VERB_RENDEZVOUS_IDX_ZTADDRESS + 5) #define ZT_PROTO_VERB_RENDEZVOUS_IDX_ADDRLEN (ZT_PROTO_VERB_RENDEZVOUS_IDX_PORT + 2) #define ZT_PROTO_VERB_RENDEZVOUS_IDX_ADDRESS (ZT_PROTO_VERB_RENDEZVOUS_IDX_ADDRLEN + 1) #define ZT_PROTO_VERB_FRAME_IDX_NETWORK_ID (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_FRAME_IDX_ETHERTYPE (ZT_PROTO_VERB_FRAME_IDX_NETWORK_ID + 8) #define ZT_PROTO_VERB_FRAME_IDX_PAYLOAD (ZT_PROTO_VERB_FRAME_IDX_ETHERTYPE + 2) #define ZT_PROTO_VERB_EXT_FRAME_IDX_NETWORK_ID (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_EXT_FRAME_LEN_NETWORK_ID 8 #define ZT_PROTO_VERB_EXT_FRAME_IDX_FLAGS (ZT_PROTO_VERB_EXT_FRAME_IDX_NETWORK_ID + ZT_PROTO_VERB_EXT_FRAME_LEN_NETWORK_ID) #define ZT_PROTO_VERB_EXT_FRAME_LEN_FLAGS 1 #define ZT_PROTO_VERB_EXT_FRAME_IDX_COM (ZT_PROTO_VERB_EXT_FRAME_IDX_FLAGS + ZT_PROTO_VERB_EXT_FRAME_LEN_FLAGS) #define ZT_PROTO_VERB_EXT_FRAME_IDX_TO (ZT_PROTO_VERB_EXT_FRAME_IDX_FLAGS + ZT_PROTO_VERB_EXT_FRAME_LEN_FLAGS) #define ZT_PROTO_VERB_EXT_FRAME_LEN_TO 6 #define ZT_PROTO_VERB_EXT_FRAME_IDX_FROM (ZT_PROTO_VERB_EXT_FRAME_IDX_TO + ZT_PROTO_VERB_EXT_FRAME_LEN_TO) #define ZT_PROTO_VERB_EXT_FRAME_LEN_FROM 6 #define ZT_PROTO_VERB_EXT_FRAME_IDX_ETHERTYPE (ZT_PROTO_VERB_EXT_FRAME_IDX_FROM + ZT_PROTO_VERB_EXT_FRAME_LEN_FROM) #define ZT_PROTO_VERB_EXT_FRAME_LEN_ETHERTYPE 2 #define ZT_PROTO_VERB_EXT_FRAME_IDX_PAYLOAD (ZT_PROTO_VERB_EXT_FRAME_IDX_ETHERTYPE + ZT_PROTO_VERB_EXT_FRAME_LEN_ETHERTYPE) #define ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST_IDX_NETWORK_ID (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST_IDX_DICT_LEN (ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST_IDX_NETWORK_ID + 8) #define ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST_IDX_DICT (ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST_IDX_DICT_LEN + 2) #define ZT_PROTO_VERB_MULTICAST_GATHER_IDX_NETWORK_ID (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_MULTICAST_GATHER_IDX_FLAGS (ZT_PROTO_VERB_MULTICAST_GATHER_IDX_NETWORK_ID + 8) #define ZT_PROTO_VERB_MULTICAST_GATHER_IDX_MAC (ZT_PROTO_VERB_MULTICAST_GATHER_IDX_FLAGS + 1) #define ZT_PROTO_VERB_MULTICAST_GATHER_IDX_ADI (ZT_PROTO_VERB_MULTICAST_GATHER_IDX_MAC + 6) #define ZT_PROTO_VERB_MULTICAST_GATHER_IDX_GATHER_LIMIT (ZT_PROTO_VERB_MULTICAST_GATHER_IDX_ADI + 4) // Note: COM, GATHER_LIMIT, and SOURCE_MAC are optional, and so are specified without size #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_NETWORK_ID (ZT_PACKET_IDX_PAYLOAD) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_FLAGS (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_NETWORK_ID + 8) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_COM (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_FLAGS + 1) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_GATHER_LIMIT (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_FLAGS + 1) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_SOURCE_MAC (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_FLAGS + 1) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_DEST_MAC (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_FLAGS + 1) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_DEST_ADI (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_DEST_MAC + 6) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_ETHERTYPE (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_DEST_ADI + 4) #define ZT_PROTO_VERB_MULTICAST_FRAME_IDX_FRAME (ZT_PROTO_VERB_MULTICAST_FRAME_IDX_ETHERTYPE + 2) #define ZT_PROTO_VERB_HELLO__OK__IDX_TIMESTAMP (ZT_PROTO_VERB_OK_IDX_PAYLOAD) #define ZT_PROTO_VERB_HELLO__OK__IDX_PROTOCOL_VERSION (ZT_PROTO_VERB_HELLO__OK__IDX_TIMESTAMP + 8) #define ZT_PROTO_VERB_HELLO__OK__IDX_MAJOR_VERSION (ZT_PROTO_VERB_HELLO__OK__IDX_PROTOCOL_VERSION + 1) #define ZT_PROTO_VERB_HELLO__OK__IDX_MINOR_VERSION (ZT_PROTO_VERB_HELLO__OK__IDX_MAJOR_VERSION + 1) #define ZT_PROTO_VERB_HELLO__OK__IDX_REVISION (ZT_PROTO_VERB_HELLO__OK__IDX_MINOR_VERSION + 1) #define ZT_PROTO_VERB_WHOIS__OK__IDX_IDENTITY (ZT_PROTO_VERB_OK_IDX_PAYLOAD) #define ZT_PROTO_VERB_WHOIS__ERROR__IDX_ZTADDRESS (ZT_PROTO_VERB_ERROR_IDX_PAYLOAD) #define ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST__OK__IDX_NETWORK_ID (ZT_PROTO_VERB_OK_IDX_PAYLOAD) #define ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST__OK__IDX_DICT_LEN (ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST__OK__IDX_NETWORK_ID + 8) #define ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST__OK__IDX_DICT (ZT_PROTO_VERB_NETWORK_CONFIG_REQUEST__OK__IDX_DICT_LEN + 2) #define ZT_PROTO_VERB_MULTICAST_GATHER__OK__IDX_NETWORK_ID (ZT_PROTO_VERB_OK_IDX_PAYLOAD) #define ZT_PROTO_VERB_MULTICAST_GATHER__OK__IDX_MAC (ZT_PROTO_VERB_MULTICAST_GATHER__OK__IDX_NETWORK_ID + 8) #define ZT_PROTO_VERB_MULTICAST_GATHER__OK__IDX_ADI (ZT_PROTO_VERB_MULTICAST_GATHER__OK__IDX_MAC + 6) #define ZT_PROTO_VERB_MULTICAST_GATHER__OK__IDX_GATHER_RESULTS (ZT_PROTO_VERB_MULTICAST_GATHER__OK__IDX_ADI + 4) #define ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_NETWORK_ID (ZT_PROTO_VERB_OK_IDX_PAYLOAD) #define ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_MAC (ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_NETWORK_ID + 8) #define ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_ADI (ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_MAC + 6) #define ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_FLAGS (ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_ADI + 4) #define ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_COM_AND_GATHER_RESULTS (ZT_PROTO_VERB_MULTICAST_FRAME__OK__IDX_FLAGS + 1) // --------------------------------------------------------------------------- namespace ZeroTier { /** * ZeroTier packet * * Packet format: * <[8] random initialization vector (doubles as 64-bit packet ID)> * <[5] destination ZT address> * <[5] source ZT address> * <[1] flags/cipher (top 5 bits) and ZT hop count (last 3 bits)> * <[8] 8-bit MAC (currently first 8 bytes of poly1305 tag)> * [... -- begin encryption envelope -- ...] * <[1] encrypted flags (top 3 bits) and verb (last 5 bits)> * [... verb-specific payload ...] * * Packets smaller than 28 bytes are invalid and silently discarded. * * The flags/cipher/hops bit field is: FFCCCHHH where C is a 3-bit cipher * selection allowing up to 7 cipher suites, F is outside-envelope flags, * and H is hop count. * * The three-bit hop count is the only part of a packet that is mutable in * transit without invalidating the MAC. All other bits in the packet are * immutable. This is because intermediate nodes can increment the hop * count up to 7 (protocol max). * * http://tonyarcieri.com/all-the-crypto-code-youve-ever-written-is-probably-broken * * For unencrypted packets, MAC is computed on plaintext. Only HELLO is ever * sent in the clear, as it's the "here is my public key" message. */ class Packet : public Buffer { public: /** * A packet fragment * * Fragments are sent if a packet is larger than UDP MTU. The first fragment * is sent with its normal header with the fragmented flag set. Remaining * fragments are sent this way. * * The fragmented bit indicates that there is at least one fragment. Fragments * themselves contain the total, so the receiver must "learn" this from the * first fragment it receives. * * Fragments are sent with the following format: * <[8] packet ID of packet whose fragment this belongs to> * <[5] destination ZT address> * <[1] 0xff, a reserved address, signals that this isn't a normal packet> * <[1] total fragments (most significant 4 bits), fragment no (LS 4 bits)> * <[1] ZT hop count (top 5 bits unused and must be zero)> * <[...] fragment data> * * The protocol supports a maximum of 16 fragments. If a fragment is received * before its main packet header, it should be cached for a brief period of * time to see if its parent arrives. Loss of any fragment constitutes packet * loss; there is no retransmission mechanism. The receiver must wait for full * receipt to authenticate and decrypt; there is no per-fragment MAC. (But if * fragments are corrupt, the MAC will fail for the whole assembled packet.) */ class Fragment : public Buffer { public: Fragment() : Buffer() { } template Fragment(const Buffer &b) throw(std::out_of_range) : Buffer(b) { } Fragment(const void *data,unsigned int len) : Buffer(data,len) { } /** * Initialize from a packet * * @param p Original assembled packet * @param fragStart Start of fragment (raw index in packet data) * @param fragLen Length of fragment in bytes * @param fragNo Which fragment (>= 1, since 0 is Packet with end chopped off) * @param fragTotal Total number of fragments (including 0) * @throws std::out_of_range Packet size would exceed buffer */ Fragment(const Packet &p,unsigned int fragStart,unsigned int fragLen,unsigned int fragNo,unsigned int fragTotal) throw(std::out_of_range) { init(p,fragStart,fragLen,fragNo,fragTotal); } /** * Initialize from a packet * * @param p Original assembled packet * @param fragStart Start of fragment (raw index in packet data) * @param fragLen Length of fragment in bytes * @param fragNo Which fragment (>= 1, since 0 is Packet with end chopped off) * @param fragTotal Total number of fragments (including 0) * @throws std::out_of_range Packet size would exceed buffer */ inline void init(const Packet &p,unsigned int fragStart,unsigned int fragLen,unsigned int fragNo,unsigned int fragTotal) throw(std::out_of_range) { if ((fragStart + fragLen) > p.size()) throw std::out_of_range("Packet::Fragment: tried to construct fragment of packet past its length"); setSize(fragLen + ZT_PROTO_MIN_FRAGMENT_LENGTH); // NOTE: this copies both the IV/packet ID and the destination address. memcpy(field(ZT_PACKET_FRAGMENT_IDX_PACKET_ID,13),p.field(ZT_PACKET_IDX_IV,13),13); (*this)[ZT_PACKET_FRAGMENT_IDX_FRAGMENT_INDICATOR] = ZT_PACKET_FRAGMENT_INDICATOR; (*this)[ZT_PACKET_FRAGMENT_IDX_FRAGMENT_NO] = (char)(((fragTotal & 0xf) << 4) | (fragNo & 0xf)); (*this)[ZT_PACKET_FRAGMENT_IDX_HOPS] = 0; memcpy(field(ZT_PACKET_FRAGMENT_IDX_PAYLOAD,fragLen),p.field(fragStart,fragLen),fragLen); } /** * Get this fragment's destination * * @return Destination ZT address */ inline Address destination() const { return Address(field(ZT_PACKET_FRAGMENT_IDX_DEST,ZT_ADDRESS_LENGTH),ZT_ADDRESS_LENGTH); } /** * @return True if fragment is of a valid length */ inline bool lengthValid() const { return (size() >= ZT_PACKET_FRAGMENT_IDX_PAYLOAD); } /** * @return ID of packet this is a fragment of */ inline uint64_t packetId() const { return at(ZT_PACKET_FRAGMENT_IDX_PACKET_ID); } /** * @return Total number of fragments in packet */ inline unsigned int totalFragments() const { return (((unsigned int)((*this)[ZT_PACKET_FRAGMENT_IDX_FRAGMENT_NO]) >> 4) & 0xf); } /** * @return Fragment number of this fragment */ inline unsigned int fragmentNumber() const { return ((unsigned int)((*this)[ZT_PACKET_FRAGMENT_IDX_FRAGMENT_NO]) & 0xf); } /** * @return Fragment ZT hop count */ inline unsigned int hops() const { return (unsigned int)((*this)[ZT_PACKET_FRAGMENT_IDX_HOPS]); } /** * Increment this packet's hop count */ inline void incrementHops() { (*this)[ZT_PACKET_FRAGMENT_IDX_HOPS] = (((*this)[ZT_PACKET_FRAGMENT_IDX_HOPS]) + 1) & ZT_PROTO_MAX_HOPS; } /** * @return Length of payload in bytes */ inline unsigned int payloadLength() const { return ((size() > ZT_PACKET_FRAGMENT_IDX_PAYLOAD) ? (size() - ZT_PACKET_FRAGMENT_IDX_PAYLOAD) : 0); } /** * @return Raw packet payload */ inline const unsigned char *payload() const { return field(ZT_PACKET_FRAGMENT_IDX_PAYLOAD,size() - ZT_PACKET_FRAGMENT_IDX_PAYLOAD); } }; /** * ZeroTier protocol verbs */ enum Verb /* Max value: 32 (5 bits) */ { /* No operation, payload ignored, no reply */ VERB_NOP = 0, /* Announcement of a node's existence: * <[1] protocol version> * <[1] software major version> * <[1] software minor version> * <[2] software revision> * <[8] timestamp (ms since epoch)> * <[...] binary serialized identity (see Identity)> * <[1] destination address type> * [<[...] destination address>] * * This is the only message that ever must be sent in the clear, since it * is used to push an identity to a new peer. * * The destination address is the wire address to which this packet is * being sent, and in OK is *also* the destination address of the OK * packet. This can be used by the receiver to detect NAT, learn its real * external address if behind NAT, and detect changes to its external * address that require re-establishing connectivity. * * Destination address types and formats (not all of these are used now): * 0 - None -- no destination address data present * 1 - Ethernet address -- format: <[6] Ethernet MAC> * 4 - 6-byte IPv4 UDP address/port -- format: <[4] IP>, <[2] port> * 6 - 18-byte IPv6 UDP address/port -- format: <[16] IP>, <[2] port> * * OK payload: * <[8] timestamp (echoed from original HELLO)> * <[1] protocol version (of responder)> * <[1] software major version (of responder)> * <[1] software minor version (of responder)> * <[2] software revision (of responder)> * <[1] destination address type (for this OK, not copied from HELLO)> * [<[...] destination address>] * * ERROR has no payload. */ VERB_HELLO = 1, /* Error response: * <[1] in-re verb> * <[8] in-re packet ID> * <[1] error code> * <[...] error-dependent payload> */ VERB_ERROR = 2, /* Success response: * <[1] in-re verb> * <[8] in-re packet ID> * <[...] request-specific payload> */ VERB_OK = 3, /* Query an identity by address: * <[5] address to look up> * * OK response payload: * <[...] binary serialized identity> * * ERROR response payload: * <[5] address> */ VERB_WHOIS = 4, /* Meet another node at a given protocol address: * <[1] flags (unused, currently 0)> * <[5] ZeroTier address of peer that might be found at this address> * <[2] 16-bit protocol address port> * <[1] protocol address length (4 for IPv4, 16 for IPv6)> * <[...] protocol address (network byte order)> * * This is sent by a relaying node to initiate NAT traversal between two * peers that are communicating by way of indirect relay. The relay will * send this to both peers at the same time on a periodic basis, telling * each where it might find the other on the network. * * Upon receipt a peer sends HELLO to establish a direct link. * * Nodes should implement rate control, limiting the rate at which they * respond to these packets to prevent their use in DDOS attacks. Nodes * may also ignore these messages if a peer is not known or is not being * actively communicated with. * * No OK or ERROR is generated. */ VERB_RENDEZVOUS = 5, /* ZT-to-ZT unicast ethernet frame (shortened EXT_FRAME): * <[8] 64-bit network ID> * <[2] 16-bit ethertype> * <[...] ethernet payload> * * MAC addresses are derived from the packet's source and destination * ZeroTier addresses. This is a shortened EXT_FRAME that elides full * Ethernet framing and other optional flags and features when they * are not necessary. * * ERROR may be generated if a membership certificate is needed for a * closed network. Payload will be network ID. */ VERB_FRAME = 6, /* Full Ethernet frame with MAC addressing and optional fields: * <[8] 64-bit network ID> * <[1] flags> * [<[...] certificate of network membership>] * <[6] destination MAC or all zero for destination node> * <[6] source MAC or all zero for node of origin> * <[2] 16-bit ethertype> * <[...] ethernet payload> * * Flags: * 0x01 - Certificate of network membership is attached * * An extended frame carries full MAC addressing, making them a * superset of VERB_FRAME. They're used for bridging or when we * want to attach a certificate since FRAME does not support that. * * Multicast frames may not be sent as EXT_FRAME. * * ERROR may be generated if a membership certificate is needed for a * closed network. Payload will be network ID. */ VERB_EXT_FRAME = 7, /* DEPRECATED */ VERB_P5_MULTICAST_FRAME = 8, /* Announce interest in multicast group(s): * <[8] 64-bit network ID> * <[6] multicast Ethernet address> * <[4] multicast additional distinguishing information (ADI)> * [... additional tuples of network/address/adi ...] * * LIKEs are sent to peers with whom you have a direct peer to peer * connection, and always including root servers. * * OK/ERROR are not generated. */ VERB_MULTICAST_LIKE = 9, /* Network member certificate replication/push: * <[...] serialized certificate of membership> * [ ... additional certificates may follow ...] * * Certificate contains network ID, peer it was issued for, etc. * * OK/ERROR are not generated. */ VERB_NETWORK_MEMBERSHIP_CERTIFICATE = 10, /* Network configuration request: * <[8] 64-bit network ID> * <[2] 16-bit length of request meta-data dictionary> * <[...] string-serialized request meta-data> * [<[8] 64-bit revision of netconf we currently have>] * * This message requests network configuration from a node capable of * providing it. If the optional revision is included, a response is * only generated if there is a newer network configuration available. * * OK response payload: * <[8] 64-bit network ID> * <[2] 16-bit length of network configuration dictionary> * <[...] network configuration dictionary> * * OK returns a Dictionary (string serialized) containing the network's * configuration and IP address assignment information for the querying * node. It also contains a membership certificate that the querying * node can push to other peers to demonstrate its right to speak on * a given network. * * When a new network configuration is received, another config request * should be sent with the new netconf's revision. This confirms receipt * and also causes any subsequent changes to rapidly propagate as this * cycle will repeat until there are no changes. This is optional but * recommended behavior. * * ERROR response payload: * <[8] 64-bit network ID> * * UNSUPPORTED_OPERATION is returned if this service is not supported, * and OBJ_NOT_FOUND if the queried network ID was not found. */ VERB_NETWORK_CONFIG_REQUEST = 11, /* Network configuration refresh request: * <[...] array of 64-bit network IDs> * * This can be sent by the network controller to inform a node that it * should now make a NETWORK_CONFIG_REQUEST. * * It does not generate an OK or ERROR message, and is treated only as * a hint to refresh now. */ VERB_NETWORK_CONFIG_REFRESH = 12, /* Request endpoints for multicast distribution: * <[8] 64-bit network ID> * <[1] flags> * <[6] MAC address of multicast group being queried> * <[4] 32-bit ADI for multicast group being queried> * <[4] 32-bit requested max number of multicast peers> * [<[...] network certificate of membership>] * * Flags: * 0x01 - Network certificate of membership is attached * * This message asks a peer for additional known endpoints that have * LIKEd a given multicast group. It's sent when the sender wishes * to send multicast but does not have the desired number of recipient * peers. * * OK response payload: * <[8] 64-bit network ID> * <[6] MAC address of multicast group being queried> * <[4] 32-bit ADI for multicast group being queried> * [begin gather results -- these same fields can be in OK(MULTICAST_FRAME)] * <[4] 32-bit total number of known members in this multicast group> * <[2] 16-bit number of members enumerated in this packet> * <[...] series of 5-byte ZeroTier addresses of enumerated members> * * If no endpoints are known, OK and ERROR are both optional. It's okay * to return nothing in that case since gathering is "lazy." * * ERROR response payload: * <[8] 64-bit network ID> * <[6] MAC address of multicast group being queried> * <[4] 32-bit ADI for multicast group being queried> * * ERRORs are optional and are only generated if permission is denied, * certificate of membership is out of date, etc. */ VERB_MULTICAST_GATHER = 13, /* Multicast frame: * <[8] 64-bit network ID> * <[1] flags> * [<[...] network certificate of membership>] * [<[4] 32-bit implicit gather limit>] * [<[6] source MAC>] * <[6] destination MAC (multicast address)> * <[4] 32-bit multicast ADI (multicast address extension)> * <[2] 16-bit ethertype> * <[...] ethernet payload> * * Flags: * 0x01 - Network certificate of membership is attached * 0x02 - Implicit gather limit field is present * 0x04 - Source MAC is specified -- otherwise it's computed from sender * * OK and ERROR responses are optional. OK may be generated if there are * implicit gather results or if the recipient wants to send its own * updated certificate of network membership to the sender. ERROR may be * generated if a certificate is needed or if multicasts to this group * are no longer wanted (multicast unsubscribe). * * OK response payload: * <[8] 64-bit network ID> * <[6] MAC address of multicast group> * <[4] 32-bit ADI for multicast group> * <[1] flags> * [<[...] network certficate of membership>] * [<[...] implicit gather results if flag 0x01 is set>] * * OK flags (same bits as request flags): * 0x01 - OK includes certificate of network membership * 0x02 - OK includes implicit gather results * * ERROR response payload: * <[8] 64-bit network ID> * <[6] multicast group MAC> * <[4] 32-bit multicast group ADI> */ VERB_MULTICAST_FRAME = 14, /* Ephemeral (PFS) key push: (UNFINISHED, NOT IMPLEMENTED YET) * <[2] flags (unused and reserved, must be 0)> * <[2] length of padding / extra field section> * <[...] padding / extra field section> * <[8] 64-bit PFS key set ID sender holds for recipient (0==none)> * <[8] 64-bit PFS key set ID of this key set> * [... begin PFS key record ...] * <[1] flags> * <[1] symmetric cipher ID> * <[1] public key type ID> * <[2] public key length in bytes> * <[...] public key> * [... additional records may follow up to max packet length ...] * * This message is sent to negotiate an ephemeral key. If the recipient's * current key pair for the sender does not match the one the sender * claims to have on file, it must respond with its own SET_EPHEMERAL_KEY. * * PFS key IDs are random and must not be zero, since zero indicates that * the sender does not have an ephemeral key on file for the recipient. * * One or more records may be sent. If multiple records are present, * the first record with common symmetric cipher, public key type, * and relevant flags must be used. * * The padding section may be filled with an arbitrary amount of random * or empty payload. This may be used as a countermeasure to prevent PFS * key pushes from being recognized by packet size vs. other packets in * the stream. This also provides potential space for additional fields * that might be indicated in the future by flags. * * Flags (all unspecified flags must be zero): * 0x01 - FIPS mode, only use record if FIPS compliant crypto in use * * Symmetric cipher IDs: * 0x01 - Salsa20/12 with Poly1305 authentication (ZT default) * 0x02 - AES256-GCM combined crypto and authentication * * Public key types: * 0x01 - Curve25519 ECDH with SHA-512 KDF * 0x02 - NIST P-256 ECDH with SHA-512 KDF * * Once both peers have a PFS key, they will attempt to send PFS key * encrypted messages with the PFS flag set using the negotiated * cipher/auth type. * * Note: most of these features such as FIPS and other cipher suites are * not implemented yet. They're just specified in the protocol for future * use to support e.g. FIPS requirements. * * OK response payload: * <[8] PFS key set ID of received key set> * <[1] index in record list of chosen key record> */ VERB_SET_EPHEMERAL_KEY = 15, /* Push of potential endpoints for direct communication: * <[2] 16-bit number of paths> * <[...] paths> * * Path record format: * <[1] flags> * <[1] metric from 0 (highest priority) to 255 (lowest priority)> * <[2] length of extended path characteristics or 0 for none> * <[...] extended path characteristics> * <[1] address type> * <[1] address length in bytes> * <[...] address> * * Path record flags: * 0x01 - Forget this path if it is currently known * 0x02 - Blacklist this path, do not use * 0x04 - Reliable path (no NAT keepalives, etc. are necessary) * 0x08 - Disable encryption (trust: privacy) * 0x10 - Disable encryption and authentication (trust: ultimate) * * Address types and addresses are of the same format as the destination * address type and address in HELLO. * * The receiver may, upon receiving a push, attempt to establish a * direct link to one or more of the indicated addresses. It is the * responsibility of the sender to limit which peers it pushes direct * paths to to those with whom it has a trust relationship. The receiver * must obey any restrictions provided such as exclusivity or blacklists. * OK responses to this message are optional. * * Note that a direct path push does not imply that learned paths can't * be used unless they are blacklisted explicitly or unless flag 0x01 * is set. * * Only a subset of this functionality is currently implemented: basic * path pushing and learning. Metrics, most flags, and OK responses are * not yet implemented as of 1.0.4. * * OK response payload: * <[2] 16-bit number of active direct paths we already have> * <[2] 16-bit number of paths in push that we don't already have> * <[2] 16-bit number of new paths we are trying (or will try)> * * ERROR is presently not sent. */ VERB_PUSH_DIRECT_PATHS = 16 }; /** * Error codes for VERB_ERROR */ enum ErrorCode { /* No error, not actually used in transit */ ERROR_NONE = 0, /* Invalid request */ ERROR_INVALID_REQUEST = 1, /* Bad/unsupported protocol version */ ERROR_BAD_PROTOCOL_VERSION = 2, /* Unknown object queried (e.g. with WHOIS) */ ERROR_OBJ_NOT_FOUND = 3, /* HELLO pushed an identity whose address is already claimed */ ERROR_IDENTITY_COLLISION = 4, /* Verb or use case not supported/enabled by this node */ ERROR_UNSUPPORTED_OPERATION = 5, /* Message to private network rejected -- no unexpired certificate on file */ ERROR_NEED_MEMBERSHIP_CERTIFICATE = 6, /* Tried to join network, but you're not a member */ ERROR_NETWORK_ACCESS_DENIED_ = 7, /* extra _ to avoid Windows name conflict */ /* Multicasts to this group are not wanted */ ERROR_UNWANTED_MULTICAST = 8 }; /** * @param v Verb * @return String representation (e.g. HELLO, OK) */ static const char *verbString(Verb v) throw(); /** * @param e Error code * @return String error name */ static const char *errorString(ErrorCode e) throw(); template Packet(const Buffer &b) : Buffer(b) { } Packet(const void *data,unsigned int len) : Buffer(data,len) { } /** * Construct a new empty packet with a unique random packet ID * * Flags and hops will be zero. Other fields and data region are undefined. * Use the header access methods (setDestination() and friends) to fill out * the header. Payload should be appended; initial size is header size. */ Packet() : Buffer(ZT_PROTO_MIN_PACKET_LENGTH) { Utils::getSecureRandom(field(ZT_PACKET_IDX_IV,8),8); (*this)[ZT_PACKET_IDX_FLAGS] = 0; // zero flags, cipher ID, and hops } /** * Make a copy of a packet with a new initialization vector and destination address * * This can be used to take one draft prototype packet and quickly make copies to * encrypt for different destinations. * * @param prototype Prototype packet * @param dest Destination ZeroTier address for new packet */ Packet(const Packet &prototype,const Address &dest) : Buffer(prototype) { Utils::getSecureRandom(field(ZT_PACKET_IDX_IV,8),8); setDestination(dest); } /** * Construct a new empty packet with a unique random packet ID * * @param dest Destination ZT address * @param source Source ZT address * @param v Verb */ Packet(const Address &dest,const Address &source,const Verb v) : Buffer(ZT_PROTO_MIN_PACKET_LENGTH) { Utils::getSecureRandom(field(ZT_PACKET_IDX_IV,8),8); setDestination(dest); setSource(source); (*this)[ZT_PACKET_IDX_FLAGS] = 0; // zero flags and hops setVerb(v); } /** * Reset this packet structure for reuse in place * * @param dest Destination ZT address * @param source Source ZT address * @param v Verb */ inline void reset(const Address &dest,const Address &source,const Verb v) { setSize(ZT_PROTO_MIN_PACKET_LENGTH); Utils::getSecureRandom(field(ZT_PACKET_IDX_IV,8),8); setDestination(dest); setSource(source); (*this)[ZT_PACKET_IDX_FLAGS] = 0; // zero flags, cipher ID, and hops setVerb(v); } /** * Generate a new IV / packet ID in place * * This can be used to re-use a packet buffer multiple times to send * technically different but otherwise identical copies of the same * packet. */ inline void newInitializationVector() { Utils::getSecureRandom(field(ZT_PACKET_IDX_IV,8),8); } /** * Set this packet's destination * * @param dest ZeroTier address of destination */ inline void setDestination(const Address &dest) { dest.copyTo(field(ZT_PACKET_IDX_DEST,ZT_ADDRESS_LENGTH),ZT_ADDRESS_LENGTH); } /** * Set this packet's source * * @param source ZeroTier address of source */ inline void setSource(const Address &source) { source.copyTo(field(ZT_PACKET_IDX_SOURCE,ZT_ADDRESS_LENGTH),ZT_ADDRESS_LENGTH); } /** * Get this packet's destination * * @return Destination ZT address */ inline Address destination() const { return Address(field(ZT_PACKET_IDX_DEST,ZT_ADDRESS_LENGTH),ZT_ADDRESS_LENGTH); } /** * Get this packet's source * * @return Source ZT address */ inline Address source() const { return Address(field(ZT_PACKET_IDX_SOURCE,ZT_ADDRESS_LENGTH),ZT_ADDRESS_LENGTH); } /** * @return True if packet is of valid length */ inline bool lengthValid() const { return (size() >= ZT_PROTO_MIN_PACKET_LENGTH); } /** * @return True if packet is fragmented (expect fragments) */ inline bool fragmented() const { return (((unsigned char)(*this)[ZT_PACKET_IDX_FLAGS] & ZT_PROTO_FLAG_FRAGMENTED) != 0); } /** * Set this packet's fragmented flag * * @param f Fragmented flag value */ inline void setFragmented(bool f) { if (f) (*this)[ZT_PACKET_IDX_FLAGS] |= (char)ZT_PROTO_FLAG_FRAGMENTED; else (*this)[ZT_PACKET_IDX_FLAGS] &= (char)(~ZT_PROTO_FLAG_FRAGMENTED); } /** * @return True if compressed (result only valid if unencrypted) */ inline bool compressed() const { return (((unsigned char)(*this)[ZT_PACKET_IDX_VERB] & ZT_PROTO_VERB_FLAG_COMPRESSED) != 0); } /** * @return ZeroTier forwarding hops (0 to 7) */ inline unsigned int hops() const { return ((unsigned int)(*this)[ZT_PACKET_IDX_FLAGS] & 0x07); } /** * Increment this packet's hop count */ inline void incrementHops() { unsigned char &b = (*this)[ZT_PACKET_IDX_FLAGS]; b = (b & 0xf8) | ((b + 1) & 0x07); } /** * @return Cipher suite selector: 0 - 7 (see #defines) */ inline unsigned int cipher() const { // Note: this uses the new cipher spec field, which is incompatible with <1.0.0 peers return (((unsigned int)(*this)[ZT_PACKET_IDX_FLAGS] & 0x38) >> 3); } /** * Set this packet's cipher suite */ inline void setCipher(unsigned int c) { unsigned char &b = (*this)[ZT_PACKET_IDX_FLAGS]; b = (b & 0xc7) | (unsigned char)((c << 3) & 0x38); // bits: FFCCCHHH // DEPRECATED "encrypted" flag -- used by pre-1.0.3 peers if (c == ZT_PROTO_CIPHER_SUITE__C25519_POLY1305_SALSA2012) b |= ZT_PROTO_FLAG_ENCRYPTED; else b &= (~ZT_PROTO_FLAG_ENCRYPTED); } /** * Get this packet's unique ID (the IV field interpreted as uint64_t) * * @return Packet ID */ inline uint64_t packetId() const { return at(ZT_PACKET_IDX_IV); } /** * Set packet verb * * This also has the side-effect of clearing any verb flags, such as * compressed, and so must only be done during packet composition. * * @param v New packet verb */ inline void setVerb(Verb v) { (*this)[ZT_PACKET_IDX_VERB] = (char)v; } /** * @return Packet verb (not including flag bits) */ inline Verb verb() const { return (Verb)((*this)[ZT_PACKET_IDX_VERB] & 0x1f); } /** * @return Length of packet payload */ inline unsigned int payloadLength() const { return ((size() < ZT_PROTO_MIN_PACKET_LENGTH) ? 0 : (size() - ZT_PROTO_MIN_PACKET_LENGTH)); } /** * @return Raw packet payload */ inline const unsigned char *payload() const { return field(ZT_PACKET_IDX_PAYLOAD,size() - ZT_PACKET_IDX_PAYLOAD); } /** * Armor packet for transport * * @param key 32-byte key * @param encryptPayload If true, encrypt packet payload, else just MAC */ void armor(const void *key,bool encryptPayload); /** * Verify and (if encrypted) decrypt packet * * @param key 32-byte key * @return False if packet is invalid or failed MAC authenticity check */ bool dearmor(const void *key); /** * Attempt to compress payload if not already (must be unencrypted) * * This requires that the payload at least contain the verb byte already * set. The compressed flag in the verb is set if compression successfully * results in a size reduction. If no size reduction occurs, compression * is not done and the flag is left cleared. * * @return True if compression occurred */ bool compress(); /** * Attempt to decompress payload if it is compressed (must be unencrypted) * * If payload is compressed, it is decompressed and the compressed verb * flag is cleared. Otherwise nothing is done and true is returned. * * @return True if data is now decompressed and valid, false on error */ bool uncompress(); private: static const unsigned char ZERO_KEY[32]; /** * Deterministically mangle a 256-bit crypto key based on packet * * This uses extra data from the packet to mangle the secret, giving us an * effective IV that is somewhat more than 64 bits. This is "free" for * Salsa20 since it has negligible key setup time so using a different * key each time is fine. * * @param in Input key (32 bytes) * @param out Output buffer (32 bytes) */ inline void _salsa20MangleKey(const unsigned char *in,unsigned char *out) const { const unsigned char *d = (const unsigned char *)data(); // IV and source/destination addresses. Using the addresses divides the // key space into two halves-- A->B and B->A (since order will change). for(unsigned int i=0;i<18;++i) // 8 + (ZT_ADDRESS_LENGTH * 2) == 18 out[i] = in[i] ^ d[i]; // Flags, but with hop count masked off. Hop count is altered by forwarding // nodes. It's one of the only parts of a packet modifiable by people // without the key. out[18] = in[18] ^ (d[ZT_PACKET_IDX_FLAGS] & 0xf8); // Raw packet size in bytes -- thus each packet size defines a new // key space. out[19] = in[19] ^ (unsigned char)(size() & 0xff); out[20] = in[20] ^ (unsigned char)((size() >> 8) & 0xff); // little endian // Rest of raw key is used unchanged for(unsigned int i=21;i<32;++i) out[i] = in[i]; } }; } // namespace ZeroTier #endif