/* * ZeroTier One - Network Virtualization Everywhere * Copyright (C) 2011-2016 ZeroTier, Inc. https://www.zerotier.com/ * * 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 . */ /* * This defines the external C API for ZeroTier's core network virtualization * engine. */ #ifndef ZT_ZEROTIERONE_H #define ZT_ZEROTIERONE_H #include // For the struct sockaddr_storage structure #if defined(_WIN32) || defined(_WIN64) #include #include #include #else /* not Windows */ #include #include #include #include #endif /* Windows or not */ #ifdef __cplusplus extern "C" { #endif /****************************************************************************/ /* Core constants */ /****************************************************************************/ /** * Default UDP port for devices running a ZeroTier endpoint */ #define ZT_DEFAULT_PORT 9993 /** * Maximum MTU for ZeroTier virtual networks * * This is pretty much an unchangeable global constant. To make it change * across nodes would require logic to send ICMP packet too big messages, * which would complicate things. 1500 has been good enough on most LANs * for ages, so a larger MTU should be fine for the forseeable future. This * typically results in two UDP packets per single large frame. Experimental * results seem to show that this is good. Larger MTUs resulting in more * fragments seemed too brittle on slow/crummy links for no benefit. * * If this does change, also change it in tap.h in the tuntaposx code under * mac-tap. * * Overhead for a normal frame split into two packets: * * 1414 = 1444 (typical UDP MTU) - 28 (packet header) - 2 (ethertype) * 1428 = 1444 (typical UDP MTU) - 16 (fragment header) * SUM: 2842 * * We use 2800, which leaves some room for other payload in other types of * messages such as multicast propagation or future support for bridging. */ #define ZT_MAX_MTU 2800 /** * Maximum length of network short name */ #define ZT_MAX_NETWORK_SHORT_NAME_LENGTH 127 /** * Maximum number of pushed routes on a network */ #define ZT_MAX_NETWORK_ROUTES 32 /** * Maximum number of statically assigned IP addresses per network endpoint using ZT address management (not DHCP) */ #define ZT_MAX_ZT_ASSIGNED_ADDRESSES 16 /** * Maximum number of "specialists" on a network -- bridges, relays, etc. */ #define ZT_MAX_NETWORK_SPECIALISTS 256 /** * Maximum number of multicast group subscriptions per network */ #define ZT_MAX_NETWORK_MULTICAST_SUBSCRIPTIONS 4096 /** * Rules engine revision ID, which specifies rules engine capabilities */ #define ZT_RULES_ENGINE_REVISION 1 /** * Maximum number of base (non-capability) network rules */ #define ZT_MAX_NETWORK_RULES 1024 /** * Maximum number of per-member capabilities per network */ #define ZT_MAX_NETWORK_CAPABILITIES 128 /** * Maximum number of per-member tags per network */ #define ZT_MAX_NETWORK_TAGS 128 /** * Maximum number of direct network paths to a given peer */ #define ZT_MAX_PEER_NETWORK_PATHS 4 /** * Maximum number of trusted physical network paths */ #define ZT_MAX_TRUSTED_PATHS 16 /** * Maximum number of rules per capability */ #define ZT_MAX_CAPABILITY_RULES 64 /** * Global maximum length for capability chain of custody (including initial issue) */ #define ZT_MAX_CAPABILITY_CUSTODY_CHAIN_LENGTH 7 /** * Maximum number of hops in a ZeroTier circuit test * * This is more or less the max that can be fit in a given packet (with * fragmentation) and only one address per hop. */ #define ZT_CIRCUIT_TEST_MAX_HOPS 256 /** * Maximum number of addresses per hop in a circuit test */ #define ZT_CIRCUIT_TEST_MAX_HOP_BREADTH 8 /** * Circuit test report flag: upstream peer authorized in path (e.g. by network COM) */ #define ZT_CIRCUIT_TEST_REPORT_FLAGS_UPSTREAM_AUTHORIZED_IN_PATH 0x0000000000000001ULL /** * Maximum number of cluster members (and max member ID plus one) */ #define ZT_CLUSTER_MAX_MEMBERS 128 /** * Maximum number of physical ZeroTier addresses a cluster member can report */ #define ZT_CLUSTER_MAX_ZT_PHYSICAL_ADDRESSES 16 /** * Maximum allowed cluster message length in bytes */ #define ZT_CLUSTER_MAX_MESSAGE_LENGTH (1500 - 48) /** * Packet characteristics flag: packet direction, 1 if inbound 0 if outbound */ #define ZT_RULE_PACKET_CHARACTERISTICS_INBOUND 0x8000000000000000ULL /** * Packet characteristics flag: multicast or broadcast destination MAC */ #define ZT_RULE_PACKET_CHARACTERISTICS_MULTICAST 0x4000000000000000ULL /** * Packet characteristics flag: broadcast destination MAC */ #define ZT_RULE_PACKET_CHARACTERISTICS_BROADCAST 0x2000000000000000ULL /** * Packet characteristics flag: TCP left-most reserved bit */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_RESERVED_0 0x0000000000000800ULL /** * Packet characteristics flag: TCP middle reserved bit */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_RESERVED_1 0x0000000000000400ULL /** * Packet characteristics flag: TCP right-most reserved bit */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_RESERVED_2 0x0000000000000200ULL /** * Packet characteristics flag: TCP NS flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_NS 0x0000000000000100ULL /** * Packet characteristics flag: TCP CWR flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_CWR 0x0000000000000080ULL /** * Packet characteristics flag: TCP ECE flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_ECE 0x0000000000000040ULL /** * Packet characteristics flag: TCP URG flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_URG 0x0000000000000020ULL /** * Packet characteristics flag: TCP ACK flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_ACK 0x0000000000000010ULL /** * Packet characteristics flag: TCP PSH flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_PSH 0x0000000000000008ULL /** * Packet characteristics flag: TCP RST flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_RST 0x0000000000000004ULL /** * Packet characteristics flag: TCP SYN flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_SYN 0x0000000000000002ULL /** * Packet characteristics flag: TCP FIN flag */ #define ZT_RULE_PACKET_CHARACTERISTICS_TCP_FIN 0x0000000000000001ULL /** * A null/empty sockaddr (all zero) to signify an unspecified socket address */ extern const struct sockaddr_storage ZT_SOCKADDR_NULL; /****************************************************************************/ /* Structures and other types */ /****************************************************************************/ /** * Function return code: OK (0) or error results * * Use ZT_ResultCode_isFatal() to check for a fatal error. If a fatal error * occurs, the node should be considered to not be working correctly. These * indicate serious problems like an inaccessible data store or a compile * problem. */ enum ZT_ResultCode { /** * Operation completed normally */ ZT_RESULT_OK = 0, // Fatal errors (>0, <1000) /** * Ran out of memory */ ZT_RESULT_FATAL_ERROR_OUT_OF_MEMORY = 1, /** * Data store is not writable or has failed */ ZT_RESULT_FATAL_ERROR_DATA_STORE_FAILED = 2, /** * Internal error (e.g. unexpected exception indicating bug or build problem) */ ZT_RESULT_FATAL_ERROR_INTERNAL = 3, // Non-fatal errors (>1000) /** * Network ID not valid */ ZT_RESULT_ERROR_NETWORK_NOT_FOUND = 1000, /** * The requested operation is not supported on this version or build */ ZT_RESULT_ERROR_UNSUPPORTED_OPERATION = 1001, /** * The requestion operation was given a bad parameter or was called in an invalid state */ ZT_RESULT_ERROR_BAD_PARAMETER = 1002 }; /** * @param x Result code * @return True if result code indicates a fatal error */ #define ZT_ResultCode_isFatal(x) ((((int)(x)) > 0)&&(((int)(x)) < 1000)) /** * Status codes sent to status update callback when things happen */ enum ZT_Event { /** * Node has been initialized * * This is the first event generated, and is always sent. It may occur * before Node's constructor returns. * * Meta-data: none */ ZT_EVENT_UP = 0, /** * Node is offline -- network does not seem to be reachable by any available strategy * * Meta-data: none */ ZT_EVENT_OFFLINE = 1, /** * Node is online -- at least one upstream node appears reachable * * Meta-data: none */ ZT_EVENT_ONLINE = 2, /** * Node is shutting down * * This is generated within Node's destructor when it is being shut down. * It's done for convenience, since cleaning up other state in the event * handler may appear more idiomatic. * * Meta-data: none */ ZT_EVENT_DOWN = 3, /** * Your identity has collided with another node's ZeroTier address * * This happens if two different public keys both hash (via the algorithm * in Identity::generate()) to the same 40-bit ZeroTier address. * * This is something you should "never" see, where "never" is defined as * once per 2^39 new node initializations / identity creations. If you do * see it, you're going to see it very soon after a node is first * initialized. * * This is reported as an event rather than a return code since it's * detected asynchronously via error messages from authoritative nodes. * * If this occurs, you must shut down and delete the node, delete the * identity.secret record/file from the data store, and restart to generate * a new identity. If you don't do this, you will not be able to communicate * with other nodes. * * We'd automate this process, but we don't think silently deleting * private keys or changing our address without telling the calling code * is good form. It violates the principle of least surprise. * * You can technically get away with not handling this, but we recommend * doing so in a mature reliable application. Besides, handling this * condition is a good way to make sure it never arises. It's like how * umbrellas prevent rain and smoke detectors prevent fires. They do, right? * * Meta-data: none */ ZT_EVENT_FATAL_ERROR_IDENTITY_COLLISION = 4, /** * Trace (debugging) message * * These events are only generated if this is a TRACE-enabled build. * * Meta-data: C string, TRACE message */ ZT_EVENT_TRACE = 5, /** * VERB_USER_MESSAGE received * * These are generated when a VERB_USER_MESSAGE packet is received via * ZeroTier VL1. * * Meta-data: ZT_UserMessage structure */ ZT_EVENT_USER_MESSAGE = 6 }; /** * Node relay policy */ enum ZT_RelayPolicy { ZT_RELAY_POLICY_NEVER = 0, ZT_RELAY_POLICY_TRUSTED = 1, ZT_RELAY_POLICY_ALWAYS = 2 }; /** * User message used with ZT_EVENT_USER_MESSAGE */ typedef struct { /** * ZeroTier address of sender (least significant 40 bits) */ uint64_t origin; /** * User message type ID */ uint64_t typeId; /** * User message data (not including type ID) */ const void *data; /** * Length of data in bytes */ unsigned int length; } ZT_UserMessage; /** * Current node status */ typedef struct { /** * 40-bit ZeroTier address of this node */ uint64_t address; /** * Current world ID */ uint64_t worldId; /** * Current world revision/timestamp */ uint64_t worldTimestamp; /** * Public identity in string-serialized form (safe to send to others) * * This pointer will remain valid as long as the node exists. */ const char *publicIdentity; /** * Full identity including secret key in string-serialized form * * This pointer will remain valid as long as the node exists. */ const char *secretIdentity; /** * Node relay policy */ enum ZT_RelayPolicy relayPolicy; /** * True if some kind of connectivity appears available */ int online; } ZT_NodeStatus; /** * Virtual network status codes */ enum ZT_VirtualNetworkStatus { /** * Waiting for network configuration (also means revision == 0) */ ZT_NETWORK_STATUS_REQUESTING_CONFIGURATION = 0, /** * Configuration received and we are authorized */ ZT_NETWORK_STATUS_OK = 1, /** * Netconf master told us 'nope' */ ZT_NETWORK_STATUS_ACCESS_DENIED = 2, /** * Netconf master exists, but this virtual network does not */ ZT_NETWORK_STATUS_NOT_FOUND = 3, /** * Initialization of network failed or other internal error */ ZT_NETWORK_STATUS_PORT_ERROR = 4, /** * ZeroTier core version too old */ ZT_NETWORK_STATUS_CLIENT_TOO_OLD = 5 }; /** * Virtual network type codes */ enum ZT_VirtualNetworkType { /** * Private networks are authorized via certificates of membership */ ZT_NETWORK_TYPE_PRIVATE = 0, /** * Public networks have no access control -- they'll always be AUTHORIZED */ ZT_NETWORK_TYPE_PUBLIC = 1 }; /** * The type of a virtual network rules table entry * * These must be from 0 to 63 since the most significant two bits of each * rule type are NOT (MSB) and AND/OR. * * Each rule is composed of zero or more MATCHes followed by an ACTION. * An ACTION with no MATCHes is always taken. */ enum ZT_VirtualNetworkRuleType { // 0 to 15 reserved for actions /** * Drop frame */ ZT_NETWORK_RULE_ACTION_DROP = 0, /** * Accept and pass frame */ ZT_NETWORK_RULE_ACTION_ACCEPT = 1, /** * Forward a copy of this frame to an observer (by ZT address) */ ZT_NETWORK_RULE_ACTION_TEE = 2, /** * Exactly like TEE but mandates ACKs from observer */ ZT_NETWORK_RULE_ACTION_WATCH = 3, /** * Drop and redirect this frame to another node (by ZT address) */ ZT_NETWORK_RULE_ACTION_REDIRECT = 4, /** * Log if match and if rule debugging is enabled in the build, otherwise does nothing (for developers) */ ZT_NETWORK_RULE_ACTION_DEBUG_LOG = 5, /** * Maximum ID for an ACTION, anything higher is a MATCH */ ZT_NETWORK_RULE_ACTION__MAX_ID = 15, // 16 to 63 reserved for match criteria ZT_NETWORK_RULE_MATCH_SOURCE_ZEROTIER_ADDRESS = 24, ZT_NETWORK_RULE_MATCH_DEST_ZEROTIER_ADDRESS = 25, ZT_NETWORK_RULE_MATCH_VLAN_ID = 26, ZT_NETWORK_RULE_MATCH_VLAN_PCP = 27, ZT_NETWORK_RULE_MATCH_VLAN_DEI = 28, ZT_NETWORK_RULE_MATCH_MAC_SOURCE = 29, ZT_NETWORK_RULE_MATCH_MAC_DEST = 30, ZT_NETWORK_RULE_MATCH_IPV4_SOURCE = 31, ZT_NETWORK_RULE_MATCH_IPV4_DEST = 32, ZT_NETWORK_RULE_MATCH_IPV6_SOURCE = 33, ZT_NETWORK_RULE_MATCH_IPV6_DEST = 34, ZT_NETWORK_RULE_MATCH_IP_TOS = 35, ZT_NETWORK_RULE_MATCH_IP_PROTOCOL = 36, ZT_NETWORK_RULE_MATCH_ETHERTYPE = 37, ZT_NETWORK_RULE_MATCH_ICMP = 38, ZT_NETWORK_RULE_MATCH_IP_SOURCE_PORT_RANGE = 39, ZT_NETWORK_RULE_MATCH_IP_DEST_PORT_RANGE = 40, ZT_NETWORK_RULE_MATCH_CHARACTERISTICS = 41, ZT_NETWORK_RULE_MATCH_FRAME_SIZE_RANGE = 42, ZT_NETWORK_RULE_MATCH_RANDOM = 43, ZT_NETWORK_RULE_MATCH_TAGS_DIFFERENCE = 44, ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_AND = 45, ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_OR = 46, ZT_NETWORK_RULE_MATCH_TAGS_BITWISE_XOR = 47, ZT_NETWORK_RULE_MATCH_TAGS_EQUAL = 48, /** * Maximum ID allowed for a MATCH entry in the rules table */ ZT_NETWORK_RULE_MATCH__MAX_ID = 63 }; /** * Network flow rule * * Rules are stored in a table in which one or more match entries is followed * by an action. If more than one match precedes an action, the rule is * the AND of all matches. An action with no match is always taken since it * matches anything. If nothing matches, the default action is DROP. * * This is designed to be a more memory-efficient way of storing rules than * a wide table, yet still fast and simple to access in code. */ typedef struct { /** * Least significant 7 bits: ZT_VirtualNetworkRuleType, most significant 1 bit is NOT bit * * If the NOT bit is set, then matches will be interpreted as "does not * match." The NOT bit has no effect on actions. * * Use "& 0x7f" to get the enum and "& 0x80" to get the NOT flag. * * The union 'v' is a variant type, and this selects which field in 'v' is * actually used and valid. */ uint8_t t; /** * Union containing the value of this rule -- which field is used depends on 't' */ union { /** * IPv6 address in big-endian / network byte order and netmask bits */ struct { uint8_t ip[16]; uint8_t mask; } ipv6; /** * IPv4 address in big-endian / network byte order */ struct { uint32_t ip; uint8_t mask; } ipv4; /** * Packet characteristic flags being matched */ uint64_t characteristics; /** * IP port range -- start-end inclusive -- host byte order */ uint16_t port[2]; /** * 40-bit ZeroTier address (in least significant bits, host byte order) */ uint64_t zt; /** * 0 = never, UINT32_MAX = always */ uint32_t randomProbability; /** * 48-bit Ethernet MAC address in big-endian order */ uint8_t mac[6]; /** * VLAN ID in host byte order */ uint16_t vlanId; /** * VLAN PCP (least significant 3 bits) */ uint8_t vlanPcp; /** * VLAN DEI (single bit / boolean) */ uint8_t vlanDei; /** * Ethernet type in host byte order */ uint16_t etherType; /** * IP protocol */ uint8_t ipProtocol; /** * IP type of service a.k.a. DSCP field */ uint8_t ipTos; /** * Ethernet packet size in host byte order (start-end, inclusive) */ uint16_t frameSize[2]; /** * ICMP type and code */ struct { uint8_t type; // ICMP type, always matched uint8_t code; // ICMP code if matched uint8_t flags; // flag 0x01 means also match code, otherwise only match type } icmp; /** * For tag-related rules */ struct { uint32_t id; uint32_t value; } tag; /** * Destinations for TEE and REDIRECT */ struct { uint64_t address; uint32_t flags; uint16_t length; } fwd; } v; } ZT_VirtualNetworkRule; typedef struct { /** * 128-bit ID (GUID) of this capability */ uint64_t id[2]; /** * Expiration time (measured vs. network config timestamp issued by controller) */ uint64_t expiration; struct { uint64_t from; uint64_t to; } custody[ZT_MAX_CAPABILITY_CUSTODY_CHAIN_LENGTH]; } ZT_VirtualNetworkCapability; /** * A route to be pushed on a virtual network */ typedef struct { /** * Target network / netmask bits (in port field) or NULL or 0.0.0.0/0 for default */ struct sockaddr_storage target; /** * Gateway IP address (port ignored) or NULL (family == 0) for LAN-local (no gateway) */ struct sockaddr_storage via; /** * Route flags */ uint16_t flags; /** * Route metric (not currently used) */ uint16_t metric; } ZT_VirtualNetworkRoute; /** * An Ethernet multicast group */ typedef struct { /** * MAC address (least significant 48 bits) */ uint64_t mac; /** * Additional distinguishing information (usually zero) */ unsigned long adi; } ZT_MulticastGroup; /** * Virtual network configuration update type */ enum ZT_VirtualNetworkConfigOperation { /** * Network is coming up (either for the first time or after service restart) */ ZT_VIRTUAL_NETWORK_CONFIG_OPERATION_UP = 1, /** * Network configuration has been updated */ ZT_VIRTUAL_NETWORK_CONFIG_OPERATION_CONFIG_UPDATE = 2, /** * Network is going down (not permanently) */ ZT_VIRTUAL_NETWORK_CONFIG_OPERATION_DOWN = 3, /** * Network is going down permanently (leave/delete) */ ZT_VIRTUAL_NETWORK_CONFIG_OPERATION_DESTROY = 4 }; /** * What trust hierarchy role does this peer have? */ enum ZT_PeerRole { ZT_PEER_ROLE_LEAF = 0, // ordinary node ZT_PEER_ROLE_UPSTREAM = 1, // upstream node ZT_PEER_ROLE_ROOT = 2 // global root }; /** * Vendor ID */ enum ZT_Vendor { ZT_VENDOR_UNSPECIFIED = 0, ZT_VENDOR_ZEROTIER = 1 }; /** * Platform type */ enum ZT_Platform { ZT_PLATFORM_UNSPECIFIED = 0, ZT_PLATFORM_LINUX = 1, ZT_PLATFORM_WINDOWS = 2, ZT_PLATFORM_MACOS = 3, ZT_PLATFORM_ANDROID = 4, ZT_PLATFORM_IOS = 5, ZT_PLATFORM_SOLARIS_SMARTOS = 6, ZT_PLATFORM_FREEBSD = 7, ZT_PLATFORM_NETBSD = 8, ZT_PLATFORM_OPENBSD = 9, ZT_PLATFORM_RISCOS = 10, ZT_PLATFORM_VXWORKS = 11, ZT_PLATFORM_FREERTOS = 12, ZT_PLATFORM_SYSBIOS = 13, ZT_PLATFORM_HURD = 14, ZT_PLATFORM_WEB = 15 }; /** * Architecture type */ enum ZT_Architecture { ZT_ARCHITECTURE_UNSPECIFIED = 0, ZT_ARCHITECTURE_X86 = 1, ZT_ARCHITECTURE_X64 = 2, ZT_ARCHITECTURE_ARM32 = 3, ZT_ARCHITECTURE_ARM64 = 4, ZT_ARCHITECTURE_MIPS32 = 5, ZT_ARCHITECTURE_MIPS64 = 6, ZT_ARCHITECTURE_POWER32 = 7, ZT_ARCHITECTURE_POWER64 = 8, ZT_ARCHITECTURE_OPENRISC32 = 9, ZT_ARCHITECTURE_OPENRISC64 = 10, ZT_ARCHITECTURE_SPARC32 = 11, ZT_ARCHITECTURE_SPARC64 = 12, ZT_ARCHITECTURE_DOTNET_CLR = 13, ZT_ARCHITECTURE_JAVA_JVM = 14, ZT_ARCHITECTURE_WEB = 15 }; /** * Virtual network configuration */ typedef struct { /** * 64-bit ZeroTier network ID */ uint64_t nwid; /** * Ethernet MAC (48 bits) that should be assigned to port */ uint64_t mac; /** * Network name (from network configuration master) */ char name[ZT_MAX_NETWORK_SHORT_NAME_LENGTH + 1]; /** * Network configuration request status */ enum ZT_VirtualNetworkStatus status; /** * Network type */ enum ZT_VirtualNetworkType type; /** * Maximum interface MTU */ unsigned int mtu; /** * Recommended MTU to avoid fragmentation at the physical layer (hint) */ unsigned int physicalMtu; /** * If nonzero, the network this port belongs to indicates DHCP availability * * This is a suggestion. The underlying implementation is free to ignore it * for security or other reasons. This is simply a netconf parameter that * means 'DHCP is available on this network.' */ int dhcp; /** * If nonzero, this port is allowed to bridge to other networks * * This is informational. If this is false (0), bridged packets will simply * be dropped and bridging won't work. */ int bridge; /** * If nonzero, this network supports and allows broadcast (ff:ff:ff:ff:ff:ff) traffic */ int broadcastEnabled; /** * If the network is in PORT_ERROR state, this is the (negative) error code most recently reported */ int portError; /** * Revision number as reported by controller or 0 if still waiting for config */ unsigned long netconfRevision; /** * Number of assigned addresses */ unsigned int assignedAddressCount; /** * ZeroTier-assigned addresses (in sockaddr_storage structures) * * For IP, the port number of the sockaddr_XX structure contains the number * of bits in the address netmask. Only the IP address and port are used. * Other fields like interface number can be ignored. * * This is only used for ZeroTier-managed address assignments sent by the * virtual network's configuration master. */ struct sockaddr_storage assignedAddresses[ZT_MAX_ZT_ASSIGNED_ADDRESSES]; /** * Number of ZT-pushed routes */ unsigned int routeCount; /** * Routes (excluding those implied by assigned addresses and their masks) */ ZT_VirtualNetworkRoute routes[ZT_MAX_NETWORK_ROUTES]; } ZT_VirtualNetworkConfig; /** * A list of networks */ typedef struct { ZT_VirtualNetworkConfig *networks; unsigned long networkCount; } ZT_VirtualNetworkList; /** * Physical network path to a peer */ typedef struct { /** * Address of endpoint */ struct sockaddr_storage address; /** * Time of last send in milliseconds or 0 for never */ uint64_t lastSend; /** * Time of last receive in milliseconds or 0 for never */ uint64_t lastReceive; /** * Is this a trusted path? If so this will be its nonzero ID. */ uint64_t trustedPathId; /** * Is path expired? */ int expired; /** * Is path preferred? */ int preferred; } ZT_PeerPhysicalPath; /** * Peer status result buffer */ typedef struct { /** * ZeroTier address (40 bits) */ uint64_t address; /** * Remote major version or -1 if not known */ int versionMajor; /** * Remote minor version or -1 if not known */ int versionMinor; /** * Remote revision or -1 if not known */ int versionRev; /** * Last measured latency in milliseconds or zero if unknown */ unsigned int latency; /** * What trust hierarchy role does this device have? */ enum ZT_PeerRole role; /** * Number of paths (size of paths[]) */ unsigned int pathCount; /** * Known network paths to peer */ ZT_PeerPhysicalPath paths[ZT_MAX_PEER_NETWORK_PATHS]; } ZT_Peer; /** * List of peers */ typedef struct { ZT_Peer *peers; unsigned long peerCount; } ZT_PeerList; /** * ZeroTier circuit test configuration and path */ typedef struct { /** * Test ID -- an arbitrary 64-bit identifier */ uint64_t testId; /** * Timestamp -- sent with test and echoed back by each reporter */ uint64_t timestamp; /** * Originator credential: network ID * * If this is nonzero, a network ID will be set for this test and * the originator must be its primary network controller. This is * currently the only authorization method available, so it must * be set to run a test. */ uint64_t credentialNetworkId; /** * Hops in circuit test (a.k.a. FIFO for graph traversal) */ struct { /** * Hop flags (currently unused, must be zero) */ unsigned int flags; /** * Number of addresses in this hop (max: ZT_CIRCUIT_TEST_MAX_HOP_BREADTH) */ unsigned int breadth; /** * 40-bit ZeroTier addresses (most significant 24 bits ignored) */ uint64_t addresses[ZT_CIRCUIT_TEST_MAX_HOP_BREADTH]; } hops[ZT_CIRCUIT_TEST_MAX_HOPS]; /** * Number of hops (max: ZT_CIRCUIT_TEST_MAX_HOPS) */ unsigned int hopCount; /** * If non-zero, circuit test will report back at every hop */ int reportAtEveryHop; /** * An arbitrary user-settable pointer */ void *ptr; /** * Pointer for internal use -- initialize to zero and do not modify */ void *_internalPtr; } ZT_CircuitTest; /** * Circuit test result report */ typedef struct { /** * Sender of report (current hop) */ uint64_t current; /** * Previous hop */ uint64_t upstream; /** * 64-bit test ID */ uint64_t testId; /** * Timestamp from original test (echoed back at each hop) */ uint64_t timestamp; /** * 64-bit packet ID of packet received by the reporting device */ uint64_t sourcePacketId; /** * Flags */ uint64_t flags; /** * ZeroTier protocol-level hop count of packet received by reporting device (>0 indicates relayed) */ unsigned int sourcePacketHopCount; /** * Error code (currently unused, will be zero) */ unsigned int errorCode; /** * Remote device vendor ID */ enum ZT_Vendor vendor; /** * Remote device protocol compliance version */ unsigned int protocolVersion; /** * Software major version */ unsigned int majorVersion; /** * Software minor version */ unsigned int minorVersion; /** * Software revision */ unsigned int revision; /** * Platform / OS */ enum ZT_Platform platform; /** * System architecture */ enum ZT_Architecture architecture; /** * Local device address on which packet was received by reporting device * * This may have ss_family equal to zero (null address) if unspecified. */ struct sockaddr_storage receivedOnLocalAddress; /** * Remote address from which reporter received the test packet * * This may have ss_family set to zero (null address) if unspecified. */ struct sockaddr_storage receivedFromRemoteAddress; /** * Next hops to which packets are being or will be sent by the reporter * * In addition to reporting back, the reporter may send the test on if * there are more recipients in the FIFO. If it does this, it can report * back the address(es) that make up the next hop and the physical address * for each if it has one. The physical address being null/unspecified * typically indicates that no direct path exists and the next packet * will be relayed. */ struct { /** * 40-bit ZeroTier address */ uint64_t address; /** * Physical address or null address (ss_family == 0) if unspecified or unknown */ struct sockaddr_storage physicalAddress; } nextHops[ZT_CIRCUIT_TEST_MAX_HOP_BREADTH]; /** * Number of next hops reported in nextHops[] */ unsigned int nextHopCount; } ZT_CircuitTestReport; /** * A cluster member's status */ typedef struct { /** * This cluster member's ID (from 0 to 1-ZT_CLUSTER_MAX_MEMBERS) */ unsigned int id; /** * Number of milliseconds since last 'alive' heartbeat message received via cluster backplane address */ unsigned int msSinceLastHeartbeat; /** * Non-zero if cluster member is alive */ int alive; /** * X, Y, and Z coordinates of this member (if specified, otherwise zero) * * What these mean depends on the location scheme being used for * location-aware clustering. At present this is GeoIP and these * will be the X, Y, and Z coordinates of the location on a spherical * approximation of Earth where Earth's core is the origin (in km). * They don't have to be perfect and need only be comparable with others * to find shortest path via the standard vector distance formula. */ int x,y,z; /** * Cluster member's last reported load */ uint64_t load; /** * Number of peers */ uint64_t peers; /** * Physical ZeroTier endpoints for this member (where peers are sent when directed here) */ struct sockaddr_storage zeroTierPhysicalEndpoints[ZT_CLUSTER_MAX_ZT_PHYSICAL_ADDRESSES]; /** * Number of physical ZeroTier endpoints this member is announcing */ unsigned int numZeroTierPhysicalEndpoints; } ZT_ClusterMemberStatus; /** * ZeroTier cluster status */ typedef struct { /** * My cluster member ID (a record for 'self' is included in member[]) */ unsigned int myId; /** * Number of cluster members */ unsigned int clusterSize; /** * Cluster member statuses */ ZT_ClusterMemberStatus members[ZT_CLUSTER_MAX_MEMBERS]; } ZT_ClusterStatus; /** * An instance of a ZeroTier One node (opaque) */ typedef void ZT_Node; /****************************************************************************/ /* Callbacks used by Node API */ /****************************************************************************/ /** * Callback called to update virtual network port configuration * * This can be called at any time to update the configuration of a virtual * network port. The parameter after the network ID specifies whether this * port is being brought up, updated, brought down, or permanently deleted. * * This in turn should be used by the underlying implementation to create * and configure tap devices at the OS (or virtual network stack) layer. * * The supplied config pointer is not guaranteed to remain valid, so make * a copy if you want one. * * This should not call multicastSubscribe() or other network-modifying * methods, as this could cause a deadlock in multithreaded or interrupt * driven environments. * * This must return 0 on success. It can return any OS-dependent error code * on failure, and this results in the network being placed into the * PORT_ERROR state. */ typedef int (*ZT_VirtualNetworkConfigFunction)( ZT_Node *, /* Node */ void *, /* User ptr */ uint64_t, /* Network ID */ void **, /* Modifiable network user PTR */ enum ZT_VirtualNetworkConfigOperation, /* Config operation */ const ZT_VirtualNetworkConfig *); /* Network configuration */ /** * Function to send a frame out to a virtual network port * * Parameters: (1) node, (2) user ptr, (3) network ID, (4) source MAC, * (5) destination MAC, (6) ethertype, (7) VLAN ID, (8) frame data, * (9) frame length. */ typedef void (*ZT_VirtualNetworkFrameFunction)( ZT_Node *, /* Node */ void *, /* User ptr */ uint64_t, /* Network ID */ void **, /* Modifiable network user PTR */ uint64_t, /* Source MAC */ uint64_t, /* Destination MAC */ unsigned int, /* Ethernet type */ unsigned int, /* VLAN ID (0 for none) */ const void *, /* Frame data */ unsigned int); /* Frame length */ /** * Callback for events * * Events are generated when the node's status changes in a significant way * and on certain non-fatal errors and events of interest. The final void * parameter points to event meta-data. The type of event meta-data (and * whether it is present at all) is event type dependent. See the comments * in the definition of ZT_Event. */ typedef void (*ZT_EventCallback)( ZT_Node *, void *, enum ZT_Event, const void *); /** * Function to get an object from the data store * * Parameters: (1) object name, (2) buffer to fill, (3) size of buffer, (4) * index in object to start reading, (5) result parameter that must be set * to the actual size of the object if it exists. * * Object names can contain forward slash (/) path separators. They will * never contain .. or backslash (\), so this is safe to map as a Unix-style * path if the underlying storage permits. For security reasons we recommend * returning errors if .. or \ are used. * * The function must return the actual number of bytes read. If the object * doesn't exist, it should return -1. -2 should be returned on other errors * such as errors accessing underlying storage. * * If the read doesn't fit in the buffer, the max number of bytes should be * read. The caller may call the function multiple times to read the whole * object. */ typedef long (*ZT_DataStoreGetFunction)( ZT_Node *, void *, const char *, void *, unsigned long, unsigned long, unsigned long *); /** * Function to store an object in the data store * * Parameters: (1) node, (2) user ptr, (3) object name, (4) object data, * (5) object size, (6) secure? (bool). * * If secure is true, the file should be set readable and writable only * to the user running ZeroTier One. What this means is platform-specific. * * Name semantics are the same as the get function. This must return zero on * success. You can return any OS-specific error code on failure, as these * may be visible in logs or error messages and might aid in debugging. * * If the data pointer is null, this must be interpreted as a delete * operation. */ typedef int (*ZT_DataStorePutFunction)( ZT_Node *, void *, const char *, const void *, unsigned long, int); /** * Function to send a ZeroTier packet out over the wire * * Parameters: * (1) Node * (2) User pointer * (3) Local interface address * (4) Remote address * (5) Packet data * (6) Packet length * (7) Desired IP TTL or 0 to use default * * If there is only one local interface it is safe to ignore the local * interface address. Otherwise if running with multiple interfaces, the * correct local interface should be chosen by address unless NULL. If * the ss_family field is zero (NULL address), a random or preferred * default interface should be used. * * If TTL is nonzero, packets should have their IP TTL value set to this * value if possible. If this is not possible it is acceptable to ignore * this value and send anyway with normal or default TTL. * * The function must return zero on success and may return any error code * on failure. Note that success does not (of course) guarantee packet * delivery. It only means that the packet appears to have been sent. */ typedef int (*ZT_WirePacketSendFunction)( ZT_Node *, /* Node */ void *, /* User ptr */ const struct sockaddr_storage *, /* Local address */ const struct sockaddr_storage *, /* Remote address */ const void *, /* Packet data */ unsigned int, /* Packet length */ unsigned int); /* TTL or 0 to use default */ /** * Function to check whether a path should be used for ZeroTier traffic * * Paramters: * (1) Node * (2) User pointer * (3) ZeroTier address or 0 for none/any * (4) Local interface address * (5) Remote address * * This function must return nonzero (true) if the path should be used. * * If no path check function is specified, ZeroTier will still exclude paths * that overlap with ZeroTier-assigned and managed IP address blocks. But the * use of a path check function is recommended to ensure that recursion does * not occur in cases where addresses are assigned by the OS or managed by * an out of band mechanism like DHCP. The path check function should examine * all configured ZeroTier interfaces and check to ensure that the supplied * addresses will not result in ZeroTier traffic being sent over a ZeroTier * interface (recursion). * * Obviously this is not required in configurations where this can't happen, * such as network containers or embedded. */ typedef int (*ZT_PathCheckFunction)( ZT_Node *, /* Node */ void *, /* User ptr */ uint64_t, /* ZeroTier address */ const struct sockaddr_storage *, /* Local address */ const struct sockaddr_storage *); /* Remote address */ /** * Function to get physical addresses for ZeroTier peers * * Parameters: * (1) Node * (2) User pointer * (3) ZeroTier address (least significant 40 bits) * (4) Desried address family or -1 for any * (5) Buffer to fill with result * * If provided this function will be occasionally called to get physical * addresses that might be tried to reach a ZeroTier address. It must * return a nonzero (true) value if the result buffer has been filled * with an address. */ typedef int (*ZT_PathLookupFunction)( ZT_Node *, /* Node */ void *, /* User ptr */ uint64_t, /* ZeroTier address (40 bits) */ int, /* Desired ss_family or -1 for any */ struct sockaddr_storage *); /* Result buffer */ /****************************************************************************/ /* C Node API */ /****************************************************************************/ /** * Structure for configuring ZeroTier core callback functions */ struct ZT_Node_Callbacks { /** * Struct version -- must currently be 0 */ long version; /** * REQUIRED: Function to get objects from persistent storage */ ZT_DataStoreGetFunction dataStoreGetFunction; /** * REQUIRED: Function to store objects in persistent storage */ ZT_DataStorePutFunction dataStorePutFunction; /** * REQUIRED: Function to send packets over the physical wire */ ZT_WirePacketSendFunction wirePacketSendFunction; /** * REQUIRED: Function to inject frames into a virtual network's TAP */ ZT_VirtualNetworkFrameFunction virtualNetworkFrameFunction; /** * REQUIRED: Function to be called when virtual networks are configured or changed */ ZT_VirtualNetworkConfigFunction virtualNetworkConfigFunction; /** * REQUIRED: Function to be called to notify external code of important events */ ZT_EventCallback eventCallback; /** * OPTIONAL: Function to check whether a given physical path should be used */ ZT_PathCheckFunction pathCheckFunction; /** * OPTIONAL: Function to get hints to physical paths to ZeroTier addresses */ ZT_PathLookupFunction pathLookupFunction; }; /** * Create a new ZeroTier One node * * Note that this can take a few seconds the first time it's called, as it * will generate an identity. * * TODO: should consolidate function pointers into versioned structure for * better API stability. * * @param node Result: pointer is set to new node instance on success * @param uptr User pointer to pass to functions/callbacks * @param callbacks Callback function configuration * @param now Current clock in milliseconds * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_new(ZT_Node **node,void *uptr,const struct ZT_Node_Callbacks *callbacks,uint64_t now); /** * Delete a node and free all resources it consumes * * If you are using multiple threads, all other threads must be shut down * first. This can crash if processXXX() methods are in progress. * * @param node Node to delete */ void ZT_Node_delete(ZT_Node *node); /** * Process a packet received from the physical wire * * @param node Node instance * @param now Current clock in milliseconds * @param localAddress Local address, or point to ZT_SOCKADDR_NULL if unspecified * @param remoteAddress Origin of packet * @param packetData Packet data * @param packetLength Packet length * @param nextBackgroundTaskDeadline Value/result: set to deadline for next call to processBackgroundTasks() * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_processWirePacket( ZT_Node *node, uint64_t now, const struct sockaddr_storage *localAddress, const struct sockaddr_storage *remoteAddress, const void *packetData, unsigned int packetLength, volatile uint64_t *nextBackgroundTaskDeadline); /** * Process a frame from a virtual network port (tap) * * @param node Node instance * @param now Current clock in milliseconds * @param nwid ZeroTier 64-bit virtual network ID * @param sourceMac Source MAC address (least significant 48 bits) * @param destMac Destination MAC address (least significant 48 bits) * @param etherType 16-bit Ethernet frame type * @param vlanId 10-bit VLAN ID or 0 if none * @param frameData Frame payload data * @param frameLength Frame payload length * @param nextBackgroundTaskDeadline Value/result: set to deadline for next call to processBackgroundTasks() * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_processVirtualNetworkFrame( ZT_Node *node, uint64_t now, uint64_t nwid, uint64_t sourceMac, uint64_t destMac, unsigned int etherType, unsigned int vlanId, const void *frameData, unsigned int frameLength, volatile uint64_t *nextBackgroundTaskDeadline); /** * Perform periodic background operations * * @param node Node instance * @param now Current clock in milliseconds * @param nextBackgroundTaskDeadline Value/result: set to deadline for next call to processBackgroundTasks() * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_processBackgroundTasks(ZT_Node *node,uint64_t now,volatile uint64_t *nextBackgroundTaskDeadline); /** * Set node's relay policy * * @param node Node instance * @param rp New relay policy * @return OK(0) or error code */ enum ZT_ResultCode ZT_Node_setRelayPolicy(ZT_Node *node,enum ZT_RelayPolicy rp); /** * Join a network * * This may generate calls to the port config callback before it returns, * or these may be deffered if a netconf is not available yet. * * If we are already a member of the network, nothing is done and OK is * returned. * * @param node Node instance * @param nwid 64-bit ZeroTier network ID * @param uptr An arbitrary pointer to associate with this network (default: NULL) * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_join(ZT_Node *node,uint64_t nwid,void *uptr); /** * Leave a network * * If a port has been configured for this network this will generate a call * to the port config callback with a NULL second parameter to indicate that * the port is now deleted. * * The uptr parameter is optional and is NULL by default. If it is not NULL, * the pointer it points to is set to this network's uptr on success. * * @param node Node instance * @param nwid 64-bit network ID * @param uptr Target pointer is set to uptr (if not NULL) * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_leave(ZT_Node *node,uint64_t nwid,void **uptr); /** * Subscribe to an Ethernet multicast group * * ADI stands for additional distinguishing information. This defaults to zero * and is rarely used. Right now its only use is to enable IPv4 ARP to scale, * and this must be done. * * For IPv4 ARP, the implementation must subscribe to 0xffffffffffff (the * broadcast address) but with an ADI equal to each IPv4 address in host * byte order. This converts ARP from a non-scalable broadcast protocol to * a scalable multicast protocol with perfect address specificity. * * If this is not done, ARP will not work reliably. * * Multiple calls to subscribe to the same multicast address will have no * effect. It is perfectly safe to do this. * * This does not generate an update call to networkConfigCallback(). * * @param node Node instance * @param nwid 64-bit network ID * @param multicastGroup Ethernet multicast or broadcast MAC (least significant 48 bits) * @param multicastAdi Multicast ADI (least significant 32 bits only, use 0 if not needed) * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_multicastSubscribe(ZT_Node *node,uint64_t nwid,uint64_t multicastGroup,unsigned long multicastAdi); /** * Unsubscribe from an Ethernet multicast group (or all groups) * * If multicastGroup is zero (0), this will unsubscribe from all groups. If * you are not subscribed to a group this has no effect. * * This does not generate an update call to networkConfigCallback(). * * @param node Node instance * @param nwid 64-bit network ID * @param multicastGroup Ethernet multicast or broadcast MAC (least significant 48 bits) * @param multicastAdi Multicast ADI (least significant 32 bits only, use 0 if not needed) * @return OK (0) or error code if a fatal error condition has occurred */ enum ZT_ResultCode ZT_Node_multicastUnsubscribe(ZT_Node *node,uint64_t nwid,uint64_t multicastGroup,unsigned long multicastAdi); /** * Get this node's 40-bit ZeroTier address * * @param node Node instance * @return ZeroTier address (least significant 40 bits of 64-bit int) */ uint64_t ZT_Node_address(ZT_Node *node); /** * Get the status of this node * * @param node Node instance * @param status Buffer to fill with current node status */ void ZT_Node_status(ZT_Node *node,ZT_NodeStatus *status); /** * Get a list of known peer nodes * * The pointer returned here must be freed with freeQueryResult() * when you are done with it. * * @param node Node instance * @return List of known peers or NULL on failure */ ZT_PeerList *ZT_Node_peers(ZT_Node *node); /** * Get the status of a virtual network * * The pointer returned here must be freed with freeQueryResult() * when you are done with it. * * @param node Node instance * @param nwid 64-bit network ID * @return Network configuration or NULL if we are not a member of this network */ ZT_VirtualNetworkConfig *ZT_Node_networkConfig(ZT_Node *node,uint64_t nwid); /** * Enumerate and get status of all networks * * @param node Node instance * @return List of networks or NULL on failure */ ZT_VirtualNetworkList *ZT_Node_networks(ZT_Node *node); /** * Free a query result buffer * * Use this to free the return values of listNetworks(), listPeers(), etc. * * @param node Node instance * @param qr Query result buffer */ void ZT_Node_freeQueryResult(ZT_Node *node,void *qr); /** * Add a local interface address * * This is used to make ZeroTier aware of those local interface addresses * that you wish to use for ZeroTier communication. This is optional, and if * it is not used ZeroTier will rely upon upstream peers (and roots) to * perform empirical address discovery and NAT traversal. But the use of this * method is recommended as it improves peer discovery when both peers are * on the same LAN. * * It is the responsibility of the caller to take care that these are never * ZeroTier interface addresses, whether these are assigned by ZeroTier or * are otherwise assigned to an interface managed by this ZeroTier instance. * This can cause recursion or other undesirable behavior. * * This returns a boolean indicating whether or not the address was * accepted. ZeroTier will only communicate over certain address types * and (for IP) address classes. * * @param addr Local interface address * @return Boolean: non-zero if address was accepted and added */ int ZT_Node_addLocalInterfaceAddress(ZT_Node *node,const struct sockaddr_storage *addr); /** * Clear local interface addresses */ void ZT_Node_clearLocalInterfaceAddresses(ZT_Node *node); /** * Send a VERB_USER_MESSAGE to another ZeroTier node * * There is no delivery guarantee here. Failure can occur if the message is * too large or if dest is not a valid ZeroTier address. * * @param dest Destination ZeroTier address * @param typeId VERB_USER_MESSAGE type ID * @param data Payload data to attach to user message * @param len Length of data in bytes * @return Boolean: non-zero on success, zero on failure */ int ZT_Node_sendUserMessage(ZT_Node *node,uint64_t dest,uint64_t typeId,const void *data,unsigned int len); /** * Set peer role * * Right now this can only be used to set a peer to either LEAF or * UPSTREAM, since roots are fixed and defined by the World. * * @param ztAddress ZeroTier address (least significant 40 bits) * @param role New peer role (LEAF or UPSTREAM) */ void ZT_Node_setRole(ZT_Node *node,uint64_t ztAddress,enum ZT_PeerRole role); /** * Set a network configuration master instance for this node * * Normal nodes should not need to use this. This is for nodes with * special compiled-in support for acting as network configuration * masters / controllers. * * The supplied instance must be a C++ object that inherits from the * NetworkConfigMaster base class in node/. No type checking is performed, * so a pointer to anything else will result in a crash. * * @param node ZertTier One node * @param networkConfigMasterInstance Instance of NetworkConfigMaster C++ class or NULL to disable * @return OK (0) or error code if a fatal error condition has occurred */ void ZT_Node_setNetconfMaster(ZT_Node *node,void *networkConfigMasterInstance); /** * Initiate a VL1 circuit test * * This sends an initial VERB_CIRCUIT_TEST and reports results back to the * supplied callback until circuitTestEnd() is called. The supplied * ZT_CircuitTest structure should be initially zeroed and then filled * in with settings and hops. * * It is the caller's responsibility to call circuitTestEnd() and then * to dispose of the test structure. Otherwise this node will listen * for results forever. * * @param node Node instance * @param test Test configuration * @param reportCallback Function to call each time a report is received * @return OK or error if, for example, test is too big for a packet or support isn't compiled in */ enum ZT_ResultCode ZT_Node_circuitTestBegin(ZT_Node *node,ZT_CircuitTest *test,void (*reportCallback)(ZT_Node *, ZT_CircuitTest *,const ZT_CircuitTestReport *)); /** * Stop listening for results to a given circuit test * * This does not free the 'test' structure. The caller may do that * after calling this method to unregister it. * * Any reports that are received for a given test ID after it is * terminated are ignored. * * @param node Node instance * @param test Test configuration to unregister */ void ZT_Node_circuitTestEnd(ZT_Node *node,ZT_CircuitTest *test); /** * Initialize cluster operation * * This initializes the internal structures and state for cluster operation. * It takes two function pointers. The first is to a function that can be * used to send data to cluster peers (mechanism is not defined by Node), * and the second is to a function that can be used to get the location of * a physical address in X,Y,Z coordinate space (e.g. as cartesian coordinates * projected from the center of the Earth). * * Send function takes an arbitrary pointer followed by the cluster member ID * to send data to, a pointer to the data, and the length of the data. The * maximum message length is ZT_CLUSTER_MAX_MESSAGE_LENGTH (65535). Messages * must be delivered whole and may be dropped or transposed, though high * failure rates are undesirable and can cause problems. Validity checking or * CRC is also not required since the Node validates the authenticity of * cluster messages using cryptogrphic methods and will silently drop invalid * messages. * * Address to location function is optional and if NULL geo-handoff is not * enabled (in this case x, y, and z in clusterInit are also unused). It * takes an arbitrary pointer followed by a physical address and three result * parameters for x, y, and z. It returns zero on failure or nonzero if these * three coordinates have been set. Coordinate space is arbitrary and can be * e.g. coordinates on Earth relative to Earth's center. These can be obtained * from latitutde and longitude with versions of the Haversine formula. * * See: http://stackoverflow.com/questions/1185408/converting-from-longitude-latitude-to-cartesian-coordinates * * Neither the send nor the address to location function should block. If the * address to location function does not have a location for an address, it * should return zero and then look up the address for future use since it * will be called again in (typically) 1-3 minutes. * * Note that both functions can be called from any thread from which the * various Node functions are called, and so must be thread safe if multiple * threads are being used. * * @param node Node instance * @param myId My cluster member ID (less than or equal to ZT_CLUSTER_MAX_MEMBERS) * @param zeroTierPhysicalEndpoints Preferred physical address(es) for ZeroTier clients to contact this cluster member (for peer redirect) * @param numZeroTierPhysicalEndpoints Number of physical endpoints in zeroTierPhysicalEndpoints[] (max allowed: 255) * @param x My cluster member's X location * @param y My cluster member's Y location * @param z My cluster member's Z location * @param sendFunction Function to be called to send data to other cluster members * @param sendFunctionArg First argument to sendFunction() * @param addressToLocationFunction Function to be called to get the location of a physical address or NULL to disable geo-handoff * @param addressToLocationFunctionArg First argument to addressToLocationFunction() * @return OK or UNSUPPORTED_OPERATION if this Node was not built with cluster support */ enum ZT_ResultCode ZT_Node_clusterInit( ZT_Node *node, unsigned int myId, const struct sockaddr_storage *zeroTierPhysicalEndpoints, unsigned int numZeroTierPhysicalEndpoints, int x, int y, int z, void (*sendFunction)(void *,unsigned int,const void *,unsigned int), void *sendFunctionArg, int (*addressToLocationFunction)(void *,const struct sockaddr_storage *,int *,int *,int *), void *addressToLocationFunctionArg); /** * Add a member to this cluster * * Calling this without having called clusterInit() will do nothing. * * @param node Node instance * @param memberId Member ID (must be less than or equal to ZT_CLUSTER_MAX_MEMBERS) * @return OK or error if clustering is disabled, ID invalid, etc. */ enum ZT_ResultCode ZT_Node_clusterAddMember(ZT_Node *node,unsigned int memberId); /** * Remove a member from this cluster * * Calling this without having called clusterInit() will do nothing. * * @param node Node instance * @param memberId Member ID to remove (nothing happens if not present) */ void ZT_Node_clusterRemoveMember(ZT_Node *node,unsigned int memberId); /** * Handle an incoming cluster state message * * The message itself contains cluster member IDs, and invalid or badly * addressed messages will be silently discarded. * * Calling this without having called clusterInit() will do nothing. * * @param node Node instance * @param msg Cluster message * @param len Length of cluster message */ void ZT_Node_clusterHandleIncomingMessage(ZT_Node *node,const void *msg,unsigned int len); /** * Get the current status of the cluster from this node's point of view * * Calling this without clusterInit() or without cluster support will just * zero out the structure and show a cluster size of zero. * * @param node Node instance * @param cs Cluster status structure to fill with data */ void ZT_Node_clusterStatus(ZT_Node *node,ZT_ClusterStatus *cs); /** * Set trusted paths * * A trusted path is a physical network (network/bits) over which both * encryption and authentication can be skipped to improve performance. * Each trusted path must have a non-zero unique ID that is the same across * all participating nodes. * * We don't recommend using trusted paths at all unless you really *need* * near-bare-metal performance. Even on a LAN authentication and encryption * are never a bad thing, and anything that introduces an "escape hatch" * for encryption should be treated with the utmost care. * * Calling with NULL pointers for networks and ids and a count of zero clears * all trusted paths. * * @param node Node instance * @param networks Array of [count] networks * @param ids Array of [count] corresponding non-zero path IDs (zero path IDs are ignored) * @param count Number of trusted paths-- values greater than ZT_MAX_TRUSTED_PATHS are clipped */ void ZT_Node_setTrustedPaths(ZT_Node *node,const struct sockaddr_storage *networks,const uint64_t *ids,unsigned int count); /** * Get ZeroTier One version * * @param major Result: major version * @param minor Result: minor version * @param revision Result: revision */ void ZT_version(int *major,int *minor,int *revision); #ifdef __cplusplus } #endif #endif