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= nfq and nfct - bindings to libnetfilter_queue and libnetfilter_conntrack To build, see Makefile. Homepage: <https://github.com/sam-github/netfilter-lua> Author: <sroberts@wurldtech.com> Documentation: See below, extracted from in-source comments. ** nfq - a binding to netfilter's queue subsystem -- qhandle = nfq.open() Return an nfqueue qhandle on success, or nil,emsg,errno on failure. -- nfq.close(qhandle) Close the qhandle, freeing its resources. - fd = nfq.fd(qhandle) Return the underlying fd used by the qhandle, useful for selecting on. -- qhandle = nfq.setblocking(qhandle, [blocking]) blocking is true to set blocking, and false to set non-blocking (default is false) Return is qhandle on success, or nil,emsg,errno on failure. -- qhandle = nfq.unbind_pf(qhandle, family) Protocol family is one of "inet", "inet6". Return is qhandle on success and nil,emsg,errno on failure. -- qhandle = nfq.bind_pf(qhandle, family) Protocol family is one of "inet", "inet6". Note that sample code seems to always unbind before binding, I've no idea why, and there is no indication of whether its possible to bind to multiple address families. Return is qhandle on success and nil,emsg,errno on failure. -- qhandle = nfq.catch(qhandle, cbfn) -- verdict = cbfn(qdata) cbfn - a function called for every queued packet with one argument, qdata. It returns "accept" or "drop" meaning to do that to the packet. For no return value, the default is "accept". If the packet is accepted, the cbfn can optionally return a second argument, a string that replaces the current packet. Return qhandle on success and nil,emsg,errno on failure. -- loop = nfq.loop(cb, copy) A one shot way to catch on queue zero, the equivalent of: h = nfq.open() nfq.unbind_pf(h, "inet") nfq.bind_pf(h, "inet") q = nfq.create_queue(h, 0) nfq.set_mode(q, copy, 0xffff) ... = nfq.catch(h, cb) nfq.destroy_queue(q) nfq.close(h) return ... DEPRECATED - don't use it in new code, it will be deleted as soon as the existing users of it have been updated. -- queue = nfq.create_queue(qhandle, queuenum) queuenum is number of the queue to bind to. Return a queue on success, or nil,emsg,errno on failure. -- nfq.destroy_queue(queue) Close the queue, freeing its resources. -- queue = nfq.set_mode(queue, copy, range) queue is returned by nfq.create_queue(). copy is one of "none" (a no-op, don't use it), "meta" (copy just packet metadata), or "packet" (copy the full packet) (default is currently "packet"). range is the size of the packet to copy, and is optional (it defaults to 0xffff, larger than any ethernet packet can be, and larger than any link layer packet I'm aware of). Returns the queue on success and nil,emsg,errno on failure. -- str = nfq.get_payload(cbctx) str is the IP payload, it has been stripped of link-layer headers. ** nfct - a binding to netfilter's conntrack subsystem NOTE I know its confusing that the nfct module has functions that should be called on different kinds of objects mixed together, but unless I make full userdata out of one or both of them, thats what it has to be. Don't confuse them, or you will segfault! Also, the netfilter libraries use assert() to check for invalid argument checking, and non-type-safe APIs. The end result is you can absolutely segfault or abort if you misuse this module. -- cthandle = nfct.open(subsys, [subscription...]) subsys is "conntrack", "expect", or "both". subscription is the groups for which notifications are requested, zero or more of "none", "new", "update", "destroy", or "all" (default is "none"). Returns a conntrack handle on success, or nil,emsg,errno on failure. There is no garbage collection, nfct.fini() must be called on the handle to release it's resources. -- nfct.close(cthandle) Close the conntrack handle, freeing its resources. -- fd = nfct.fd(cthandle) Return the underlying fd used by the conntrack handle, useful for selecting on. -- cthandle = nfct.setblocking(cthandle, [blocking]) blocking is true to set blocking, and false to set non-blocking (default is false) Return is cthandle on success, or nil,emsg,errno on failure. -- cthandle = nfct.ct_callback_register(cthandle, ctcb, ctmsgtype) -- cthandle = nfct.exp_callback_register(cthandle, expcb, ctmsgtype) For each subsystem (conntrack and expect) only one registration can be active at a time, the latest call replaces any previous ones. Callbacks can't be registered for a subsystem that wasn't opened. The callback function will be called as either verdict = ctcb(ctmsgtype, ct) verdict = expcb(ctmsgtype, exp) depending on which register is called. Since you can't know the type of the object, use different callback functions. ctmsgtype is one of "new", "update", "destroy", "all", or "error" (default is "all"). The callback can return any of "failure", "stop", "continue", or "stolen" (the default is "continue"): "failure" will stop the loop, "continue" will continue with the next message, and "stolen" is like continue, except the conntrack or expect object will not be destroyed (the user must destroy it later with the appropriate nfct.destroy() or nfct.exp_destroy or resources will be leaked) Returns cthandle on success, nil,emsg,errno on failure. -- cthandle = nfct.catch(cthandle) Return is the cthandle on success, or nil,emsg,errno on failure. -- nfct.loop(cthandle, ctmsgtype, ctcb) Equivalent to nfct.ct_callback_register(cthandle, ctcb, ctmsgtype) return nfct.catch(cthandle) Will probably be removed soon. -- ct = nfct.new() Create a new conntrack context (NOT a conntrack handle). No garbage collection on the context is done, it must be destroyed with nfct.destroy() or resources will be leaked. Return is the conntrack context on sucess, and nil,emsg,errno on failure (but it can only fail if malloc fails). -- nfct.destroy(ct) Destroy a conntrack context. Note that only contexts created with nfct.new() should be destroyed - in particular, the ct passed in a nfct.loop() callback should NOT be destroyed. -- str = nfct.tostring(ct, ctmsgtype) ctmsgtype is one of "new", "update", "destroy", or nil (meaning msg type is unknown). Returns a string representation of a conntrack. -- ct = nfct.setobjopt(ct, option) Sets an option on a conntrack context, option is one of: "undo-snat", "undo-dnat", "undo-spat", "undo-dpat", "setup-original", "setup-reply" Returns ct on success so calls can be chained, and nil,emsg,errno on failure. -- value = nfct.get_attr_u8(ct, attr) -- value = nfct.get_attr_u16(ct, attr) -- value = nfct.get_attr_u32(ct, attr) -- value = nfct.get_attr_n16(ct, attr) -- value = nfct.get_attr_n32(ct, attr) -- value = nfct.get_attr_port(ct, attr) No error checking is done, values of zero will be returned for attributes that aren't present, and undefined values will be returned for attributes that aren't actually of the type requested. Also, the attribute value may be in network byte order. ct is a conntrack context (NOT a conntrack handle, do not mix the two). get_attr_n#() is like the "u" version, but it converts the number from network to host byte order. get_attr_port() is an alias for get_attr_n16(), since TCP and UDP ports are n16. attr is one of the enum nf_conntrack_attr values, where some aliases are provided for the more commonly used origin attributes: orig-ipv4-src -- ATTR_ORIG_IPV4_SRC, u32 bits ipv4-src -- ATTR_IPV4_SRC, alias orig-ipv4-dst -- ATTR_ORIG_IPV4_DST, u32 bits ipv4-dst -- ATTR_IPV4_DST, alias repl-ipv4-src -- ATTR_REPL_IPV4_SRC, u32 bits repl-ipv4-dst -- ATTR_REPL_IPV4_DST, u32 bits orig-ipv6-src -- ATTR_ORIG_IPV6_SRC, u128 bits ipv6-src -- ATTR_IPV6_SRC, alias orig-ipv6-dst -- ATTR_ORIG_IPV6_DST, u128 bits ipv6-dst -- ATTR_IPV6_DST, alias repl-ipv6-src -- ATTR_REPL_IPV6_SRC, u128 bits repl-ipv6-dst -- ATTR_REPL_IPV6_DST, u128 bits orig-port-src -- ATTR_ORIG_PORT_SRC, u16 bits port-src -- ATTR_PORT_SRC, alias orig-port-dst -- ATTR_ORIG_PORT_DST, u16 bits port-dst -- ATTR_PORT_DST, alias repl-port-src -- ATTR_REPL_PORT_SRC, u16 bits repl-port-dst -- ATTR_REPL_PORT_DST, u16 bits icmp-type -- ATTR_ICMP_TYPE, u8 bits icmp-code -- ATTR_ICMP_CODE, u8 bits icmp-id -- ATTR_ICMP_ID, u16 bits orig-l3proto -- ATTR_ORIG_L3PROTO, u8 bits l3proto -- ATTR_L3PROTO, alias repl-l3proto -- ATTR_REPL_L3PROTO, u8 bits orig-l4proto -- ATTR_ORIG_L4PROTO, u8 bits l4proto -- ATTR_L4PROTO, alias repl-l4proto -- ATTR_REPL_L4PROTO, u8 bits tcp-state -- ATTR_TCP_STATE, u8 bits snat-ipv4 -- ATTR_SNAT_IPV4, u32 bits dnat-ipv4 -- ATTR_DNAT_IPV4, u32 bits snat-port -- ATTR_SNAT_PORT, u16 bits dnat-port -- ATTR_DNAT_PORT, u16 bits timeout -- ATTR_TIMEOUT, u32 bits mark -- ATTR_MARK, u32 bits orig-counter-packets -- ATTR_ORIG_COUNTER_PACKETS, u32 bits repl-counter-packets -- ATTR_REPL_COUNTER_PACKETS, u32 bits orig-counter-bytes -- ATTR_ORIG_COUNTER_BYTES, u32 bits repl-counter-bytes -- ATTR_REPL_COUNTER_BYTES, u32 bits use -- ATTR_USE, u32 bits id -- ATTR_ID, u32 bits status -- ATTR_STATUS, u32 bits tcp-flags-orig -- ATTR_TCP_FLAGS_ORIG, u8 bits tcp-flags-repl -- ATTR_TCP_FLAGS_REPL, u8 bits tcp-mask-orig -- ATTR_TCP_MASK_ORIG, u8 bits tcp-mask-repl -- ATTR_TCP_MASK_REPL, u8 bits master-ipv4-src -- ATTR_MASTER_IPV4_SRC, u32 bits master-ipv4-dst -- ATTR_MASTER_IPV4_DST, u32 bits master-ipv6-src -- ATTR_MASTER_IPV6_SRC, u128 bits master-ipv6-dst -- ATTR_MASTER_IPV6_DST, u128 bits master-port-src -- ATTR_MASTER_PORT_SRC, u16 bits master-port-dst -- ATTR_MASTER_PORT_DST, u16 bits master-l3proto -- ATTR_MASTER_L3PROTO, u8 bits master-l4proto -- ATTR_MASTER_L4PROTO, u8 bits secmark -- ATTR_SECMARK, u32 bits orig-nat-seq-correction-pos -- ATTR_ORIG_NAT_SEQ_CORRECTION_POS, u32 bits orig-nat-seq-offset-before -- ATTR_ORIG_NAT_SEQ_OFFSET_BEFORE, u32 bits orig-nat-seq-offset-after -- ATTR_ORIG_NAT_SEQ_OFFSET_AFTER, u32 bits repl-nat-seq-correction-pos -- ATTR_REPL_NAT_SEQ_CORRECTION_POS, u32 bits repl-nat-seq-offset-before -- ATTR_REPL_NAT_SEQ_OFFSET_BEFORE, u32 bits repl-nat-seq-offset-after -- ATTR_REPL_NAT_SEQ_OFFSET_AFTER, u32 bits sctp-state -- ATTR_SCTP_STATE, u8 bits sctp-vtag-orig -- ATTR_SCTP_VTAG_ORIG, u32 bits sctp-vtag-repl -- ATTR_SCTP_VTAG_REPL, u32 bits helper-name -- ATTR_HELPER_NAME, string (30 bytes max) dccp-state -- ATTR_DCCP_STATE, u8 bits dccp-role -- ATTR_DCCP_ROLE, u8 bits dccp-handshake-seq -- ATTR_DCCP_HANDSHAKE_SEQ, u64 bits -- ct = nfct.set_attr_u8(ct, attr, value) -- ct = nfct.set_attr_u16(ct, attr, value) -- ct = nfct.set_attr_u32(ct, attr, value) -- ct = nfct.set_attr_n16(ct, attr, value) -- ct = nfct.set_attr_n32(ct, attr, value) -- ct = nfct.set_attr_port(ct, attr, value) No error checking is done, value will be cast to the necessary type, and who knows what will happen for values that aren't actually of the correct type for the attribute. The attribute value may need to be in network byte order. ct is a conntrack context (NOT a conntrack handle, do not mix the two). See nfct.get_attr_*() for the supported attr names and types. Returns the conntrack conntext, so calls can be chained. -- ct = nfct.set_attr_ipv4(ct, attr, value) Get an attribute as a string, the internet address in presentation format. See inet_ntop(3) for more information. Return is the presentation address, or nil,emsg,errno on failure. -- ct = nfct.set_attr_ipv4(ct, attr, value) -- ct = nfct.set_attr_ipv6(ct, attr, value) Set an attribute as a string, the internet address in presentation format. See inet_ntop(3) for more information. Returns the conntrack conntext, so calls can be chained. -- value = nfct.get_attr_pf(ct, attr) -- ct = nfct.set_attr_pf(ct, attr, value) Set or get attributes with address family/protocol values as a string, for example, the "l3proto". The address families, such as AF_INET and AF_INET6, are defined in the system headers to be identical to the equivalent protocol family. Value is one of: unspec -- PF_UNSPEC, Unspecified. local -- PF_LOCAL, Local to host (pipes and file-domain). unix -- PF_UNIX, POSIX name for PF_LOCAL. file -- PF_FILE, Another non-standard name for PF_LOCAL. inet -- PF_INET, IP protocol family. ax25 -- PF_AX25, Amateur Radio AX.25. ipx -- PF_IPX, Novell Internet Protocol. appletalk -- PF_APPLETALK, Appletalk DDP. netrom -- PF_NETROM, Amateur radio NetROM. bridge -- PF_BRIDGE, Multiprotocol bridge. atmpvc -- PF_ATMPVC, ATM PVCs. x25 -- PF_X25, Reserved for X.25 project. inet6 -- PF_INET6, IP version 6. rose -- PF_ROSE, Amateur Radio X.25 PLP. decnet -- PF_DECnet, Reserved for DECnet project. netbeui -- PF_NETBEUI, Reserved for 802.2LLC project. security -- PF_SECURITY, Security callback pseudo AF. key -- PF_KEY, PF_KEY key management API. netlink -- PF_NETLINK route -- PF_ROUTE, Alias to emulate 4.4BSD. packet -- PF_PACKET, Packet family. ash -- PF_ASH, Ash. econet -- PF_ECONET, Acorn Econet. atmsvc -- PF_ATMSVC, ATM SVCs. rds -- PF_RDS, RDS sockets. sna -- PF_SNA, Linux SNA Project irda -- PF_IRDA, IRDA sockets. pppox -- PF_PPPOX, PPPoX sockets. wanpipe -- PF_WANPIPE, Wanpipe API sockets. llc -- PF_LLC, Linux LLC. can -- PF_CAN, Controller Area Network. tipc -- PF_TIPC, TIPC sockets. bluetooth -- PF_BLUETOOTH, Bluetooth sockets. iucv -- PF_IUCV, IUCV sockets. rxrpc -- PF_RXRPC, RxRPC sockets. isdn -- PF_ISDN, mISDN sockets. phonet -- PF_PHONET, Phonet sockets. ieee802154-- PF_IEEE802154, IEEE 802.15.4 sockets. Get returns the value as a string if it is known, or a number if it is not. Set returns the conntrack conntext, so calls can be chained. -- value = nfct.get_attr_ipproto(ct, attr) -- ct = nfct.set_attr_ipproto(ct, attr, value) Set or get attributes with IP protocol values as a string, for example, the "l4proto" attribute if the "l3proto" is "inet" or "inet6". Value is one of: ip -- IPPROTO_IP, Dummy protocol for TCP. hopopts -- IPPROTO_HOPOPTS, IPv6 Hop-by-Hop options. icmp -- IPPROTO_ICMP, Internet Control Message Protocol. igmp -- IPPROTO_IGMP, Internet Group Management Protocol. ipip -- IPPROTO_IPIP, IPIP tunnels (older KA9Q tunnels use 94). tcp -- IPPROTO_TCP, Transmission Control Protocol. egp -- IPPROTO_EGP, Exterior Gateway Protocol. pup -- IPPROTO_PUP, PUP protocol. udp -- IPPROTO_UDP, User Datagram Protocol. idp -- IPPROTO_IDP, XNS IDP protocol. tp -- IPPROTO_TP, SO Transport Protocol Class 4. dccp -- IPPROTO_DCCP, Datagram Congestion Control Protocol. ipv6 -- IPPROTO_IPV6, IPv6 header. routing -- IPPROTO_ROUTING, IPv6 routing header. fragment -- IPPROTO_FRAGMENT, IPv6 fragmentation header. rsvp -- IPPROTO_RSVP, Reservation Protocol. gre -- IPPROTO_GRE, General Routing Encapsulation. esp -- IPPROTO_ESP, encapsulating security payload. ah -- IPPROTO_AH, authentication header. icmpv6 -- IPPROTO_ICMPV6, ICMPv6. none -- IPPROTO_NONE, IPv6 no next header. dstopts -- IPPROTO_DSTOPTS, IPv6 destination options. mtp -- IPPROTO_MTP, Multicast Transport Protocol. encap -- IPPROTO_ENCAP, Encapsulation Header. pim -- IPPROTO_PIM, Protocol Independent Multicast. comp -- IPPROTO_COMP, Compression Header Protocol. sctp -- IPPROTO_SCTP, Stream Control Transmission Protocol. udplite -- IPPROTO_UDPLITE, UDP-Lite protocol. raw -- IPPROTO_RAW, Raw IP packets. Get returns the value as a string if it is known, or a number if it is not. Set returns the conntrack conntext, so calls can be chained. -- exp = nfct.exp_new(ctmaster, ctexpected, ctmask, timeout, flags...) master, expected, mask are all ct objects, see nfct.new(). timeout is in seconds the expectation will wait for a connection flags is one or more of "permanent", "inactive", or "userspace", and is optional (default is no flags). permanent means the expectation remains in place until timeout, even if when connections match (the default is to clear the connection after an expectaion matches). userspace appears to be true for all expectations created using this API, I don't know why its there, and I've no idea what inactive means. -- str = nfct.exp_tostring(exp, ctmsgtype) ctmsgtype is one of "new", "update", "destroy", or nil (meaning msg type is unknown). Returns a string representation of an expectation. -- cthandle = nfct.exp_query(cthandle, qtype, data) Currently, only create and destroy is supported. create -- NFCT_Q_CREATE, data must be an exp object update -- NFCT_Q_UPDATE destroy -- NFCT_Q_DESTROY, data must be an exp object get -- NFCT_Q_GET flush -- NFCT_Q_FLUSH dump -- NFCT_Q_DUMP dump-reset -- NFCT_Q_DUMP_RESET create-update -- NFCT_Q_CREATE_UPDATE -- h = nfct.ntohs(n) -- n = nfct.htons(h) Convert a short between network and host byte order. No error or bounds checking on the numbers is done.
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lua bindings for netfilter (nfq for libnetfilter_queue and nfct for libnetfilter_conntrack)
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