// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package strace import ( "fmt" "strings" "gvisor.dev/gvisor/pkg/abi" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/bits" "gvisor.dev/gvisor/pkg/hostarch" "gvisor.dev/gvisor/pkg/marshal/primitive" "gvisor.dev/gvisor/pkg/sentry/kernel" "gvisor.dev/gvisor/pkg/sentry/socket" "gvisor.dev/gvisor/pkg/sentry/socket/netlink" slinux "gvisor.dev/gvisor/pkg/sentry/syscalls/linux" ) // SocketFamily are the possible socket(2) families. var SocketFamily = abi.ValueSet{ linux.AF_UNSPEC: "AF_UNSPEC", linux.AF_UNIX: "AF_UNIX", linux.AF_INET: "AF_INET", linux.AF_AX25: "AF_AX25", linux.AF_IPX: "AF_IPX", linux.AF_APPLETALK: "AF_APPLETALK", linux.AF_NETROM: "AF_NETROM", linux.AF_BRIDGE: "AF_BRIDGE", linux.AF_ATMPVC: "AF_ATMPVC", linux.AF_X25: "AF_X25", linux.AF_INET6: "AF_INET6", linux.AF_ROSE: "AF_ROSE", linux.AF_DECnet: "AF_DECnet", linux.AF_NETBEUI: "AF_NETBEUI", linux.AF_SECURITY: "AF_SECURITY", linux.AF_KEY: "AF_KEY", linux.AF_NETLINK: "AF_NETLINK", linux.AF_PACKET: "AF_PACKET", linux.AF_ASH: "AF_ASH", linux.AF_ECONET: "AF_ECONET", linux.AF_ATMSVC: "AF_ATMSVC", linux.AF_RDS: "AF_RDS", linux.AF_SNA: "AF_SNA", linux.AF_IRDA: "AF_IRDA", linux.AF_PPPOX: "AF_PPPOX", linux.AF_WANPIPE: "AF_WANPIPE", linux.AF_LLC: "AF_LLC", linux.AF_IB: "AF_IB", linux.AF_MPLS: "AF_MPLS", linux.AF_CAN: "AF_CAN", linux.AF_TIPC: "AF_TIPC", linux.AF_BLUETOOTH: "AF_BLUETOOTH", linux.AF_IUCV: "AF_IUCV", linux.AF_RXRPC: "AF_RXRPC", linux.AF_ISDN: "AF_ISDN", linux.AF_PHONET: "AF_PHONET", linux.AF_IEEE802154: "AF_IEEE802154", linux.AF_CAIF: "AF_CAIF", linux.AF_ALG: "AF_ALG", linux.AF_NFC: "AF_NFC", linux.AF_VSOCK: "AF_VSOCK", } // SocketType are the possible socket(2) types. var SocketType = abi.ValueSet{ uint64(linux.SOCK_STREAM): "SOCK_STREAM", uint64(linux.SOCK_DGRAM): "SOCK_DGRAM", uint64(linux.SOCK_RAW): "SOCK_RAW", uint64(linux.SOCK_RDM): "SOCK_RDM", uint64(linux.SOCK_SEQPACKET): "SOCK_SEQPACKET", uint64(linux.SOCK_DCCP): "SOCK_DCCP", uint64(linux.SOCK_PACKET): "SOCK_PACKET", } // SocketFlagSet are the possible socket(2) flags. var SocketFlagSet = abi.FlagSet{ { Flag: linux.SOCK_CLOEXEC, Name: "SOCK_CLOEXEC", }, { Flag: linux.SOCK_NONBLOCK, Name: "SOCK_NONBLOCK", }, } // ipProtocol are the possible socket(2) types for INET and INET6 sockets. var ipProtocol = abi.ValueSet{ linux.IPPROTO_IP: "IPPROTO_IP", linux.IPPROTO_ICMP: "IPPROTO_ICMP", linux.IPPROTO_IGMP: "IPPROTO_IGMP", linux.IPPROTO_IPIP: "IPPROTO_IPIP", linux.IPPROTO_TCP: "IPPROTO_TCP", linux.IPPROTO_EGP: "IPPROTO_EGP", linux.IPPROTO_PUP: "IPPROTO_PUP", linux.IPPROTO_UDP: "IPPROTO_UDP", linux.IPPROTO_IDP: "IPPROTO_IDP", linux.IPPROTO_TP: "IPPROTO_TP", linux.IPPROTO_DCCP: "IPPROTO_DCCP", linux.IPPROTO_IPV6: "IPPROTO_IPV6", linux.IPPROTO_RSVP: "IPPROTO_RSVP", linux.IPPROTO_GRE: "IPPROTO_GRE", linux.IPPROTO_ESP: "IPPROTO_ESP", linux.IPPROTO_AH: "IPPROTO_AH", linux.IPPROTO_MTP: "IPPROTO_MTP", linux.IPPROTO_BEETPH: "IPPROTO_BEETPH", linux.IPPROTO_ENCAP: "IPPROTO_ENCAP", linux.IPPROTO_PIM: "IPPROTO_PIM", linux.IPPROTO_COMP: "IPPROTO_COMP", linux.IPPROTO_SCTP: "IPPROTO_SCTP", linux.IPPROTO_UDPLITE: "IPPROTO_UDPLITE", linux.IPPROTO_MPLS: "IPPROTO_MPLS", linux.IPPROTO_RAW: "IPPROTO_RAW", } // SocketProtocol are the possible socket(2) protocols for each protocol family. var SocketProtocol = map[int32]abi.ValueSet{ linux.AF_INET: ipProtocol, linux.AF_INET6: ipProtocol, linux.AF_NETLINK: { linux.NETLINK_ROUTE: "NETLINK_ROUTE", linux.NETLINK_UNUSED: "NETLINK_UNUSED", linux.NETLINK_USERSOCK: "NETLINK_USERSOCK", linux.NETLINK_FIREWALL: "NETLINK_FIREWALL", linux.NETLINK_SOCK_DIAG: "NETLINK_SOCK_DIAG", linux.NETLINK_NFLOG: "NETLINK_NFLOG", linux.NETLINK_XFRM: "NETLINK_XFRM", linux.NETLINK_SELINUX: "NETLINK_SELINUX", linux.NETLINK_ISCSI: "NETLINK_ISCSI", linux.NETLINK_AUDIT: "NETLINK_AUDIT", linux.NETLINK_FIB_LOOKUP: "NETLINK_FIB_LOOKUP", linux.NETLINK_CONNECTOR: "NETLINK_CONNECTOR", linux.NETLINK_NETFILTER: "NETLINK_NETFILTER", linux.NETLINK_IP6_FW: "NETLINK_IP6_FW", linux.NETLINK_DNRTMSG: "NETLINK_DNRTMSG", linux.NETLINK_KOBJECT_UEVENT: "NETLINK_KOBJECT_UEVENT", linux.NETLINK_GENERIC: "NETLINK_GENERIC", linux.NETLINK_SCSITRANSPORT: "NETLINK_SCSITRANSPORT", linux.NETLINK_ECRYPTFS: "NETLINK_ECRYPTFS", linux.NETLINK_RDMA: "NETLINK_RDMA", linux.NETLINK_CRYPTO: "NETLINK_CRYPTO", }, } var controlMessageType = map[int32]string{ linux.SCM_RIGHTS: "SCM_RIGHTS", linux.SCM_CREDENTIALS: "SCM_CREDENTIALS", linux.SO_TIMESTAMP: "SO_TIMESTAMP", } func unmarshalControlMessageRights(src []byte) linux.ControlMessageRights { count := len(src) / linux.SizeOfControlMessageRight cmr := make(linux.ControlMessageRights, count) for i, _ := range cmr { cmr[i] = int32(hostarch.ByteOrder.Uint32(src[i*linux.SizeOfControlMessageRight:])) } return cmr } func cmsghdr(t *kernel.Task, addr hostarch.Addr, length uint64, maxBytes uint64) string { if length > maxBytes { return fmt.Sprintf("%#x (error decoding control: invalid length (%d))", addr, length) } buf := make([]byte, length) if _, err := t.CopyInBytes(addr, buf); err != nil { return fmt.Sprintf("%#x (error decoding control: %v)", addr, err) } var strs []string for i := 0; i < len(buf); { if i+linux.SizeOfControlMessageHeader > len(buf) { strs = append(strs, "{invalid control message (too short)}") break } var h linux.ControlMessageHeader h.UnmarshalUnsafe(buf[i : i+linux.SizeOfControlMessageHeader]) var skipData bool level := "SOL_SOCKET" if h.Level != linux.SOL_SOCKET { skipData = true level = fmt.Sprint(h.Level) } typ, ok := controlMessageType[h.Type] if !ok { skipData = true typ = fmt.Sprint(h.Type) } if h.Length > uint64(len(buf)-i) { strs = append(strs, fmt.Sprintf( "{level=%s, type=%s, length=%d, content extends beyond buffer}", level, typ, h.Length, )) break } i += linux.SizeOfControlMessageHeader width := t.Arch().Width() length := int(h.Length) - linux.SizeOfControlMessageHeader if length < 0 { strs = append(strs, fmt.Sprintf( "{level=%s, type=%s, length=%d, content too short}", level, typ, h.Length, )) break } if skipData { strs = append(strs, fmt.Sprintf("{level=%s, type=%s, length=%d}", level, typ, h.Length)) i += bits.AlignUp(length, width) continue } switch h.Type { case linux.SCM_RIGHTS: rightsSize := bits.AlignDown(length, linux.SizeOfControlMessageRight) fds := unmarshalControlMessageRights(buf[i : i+rightsSize]) rights := make([]string, 0, len(fds)) for _, fd := range fds { rights = append(rights, fmt.Sprint(fd)) } strs = append(strs, fmt.Sprintf( "{level=%s, type=%s, length=%d, content: %s}", level, typ, h.Length, strings.Join(rights, ","), )) case linux.SCM_CREDENTIALS: if length < linux.SizeOfControlMessageCredentials { strs = append(strs, fmt.Sprintf( "{level=%s, type=%s, length=%d, content too short}", level, typ, h.Length, )) break } var creds linux.ControlMessageCredentials creds.UnmarshalUnsafe(buf[i : i+linux.SizeOfControlMessageCredentials]) strs = append(strs, fmt.Sprintf( "{level=%s, type=%s, length=%d, pid: %d, uid: %d, gid: %d}", level, typ, h.Length, creds.PID, creds.UID, creds.GID, )) case linux.SO_TIMESTAMP: if length < linux.SizeOfTimeval { strs = append(strs, fmt.Sprintf( "{level=%s, type=%s, length=%d, content too short}", level, typ, h.Length, )) break } var tv linux.Timeval tv.UnmarshalUnsafe(buf[i : i+linux.SizeOfTimeval]) strs = append(strs, fmt.Sprintf( "{level=%s, type=%s, length=%d, Sec: %d, Usec: %d}", level, typ, h.Length, tv.Sec, tv.Usec, )) default: panic("unreachable") } i += bits.AlignUp(length, width) } return fmt.Sprintf("%#x %s", addr, strings.Join(strs, ", ")) } func msghdr(t *kernel.Task, addr hostarch.Addr, printContent bool, maxBytes uint64) string { var msg slinux.MessageHeader64 if _, err := msg.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding msghdr: %v)", addr, err) } s := fmt.Sprintf( "%#x {name=%#x, namelen=%d, iovecs=%s", addr, msg.Name, msg.NameLen, iovecs(t, hostarch.Addr(msg.Iov), int(msg.IovLen), printContent, maxBytes), ) if printContent { s = fmt.Sprintf("%s, control={%s}", s, cmsghdr(t, hostarch.Addr(msg.Control), msg.ControlLen, maxBytes)) } else { s = fmt.Sprintf("%s, control=%#x, control_len=%d", s, msg.Control, msg.ControlLen) } return fmt.Sprintf("%s, flags=%d}", s, msg.Flags) } func sockAddr(t *kernel.Task, addr hostarch.Addr, length uint32) string { if addr == 0 { return "null" } b, err := slinux.CaptureAddress(t, addr, length) if err != nil { return fmt.Sprintf("%#x {error reading address: %v}", addr, err) } // Extract address family. if len(b) < 2 { return fmt.Sprintf("%#x {address too short: %d bytes}", addr, len(b)) } family := hostarch.ByteOrder.Uint16(b) familyStr := SocketFamily.Parse(uint64(family)) switch family { case linux.AF_INET, linux.AF_INET6, linux.AF_UNIX: fa, _, err := socket.AddressAndFamily(b) if err != nil { return fmt.Sprintf("%#x {Family: %s, error extracting address: %v}", addr, familyStr, err) } if family == linux.AF_UNIX { return fmt.Sprintf("%#x {Family: %s, Addr: %q}", addr, familyStr, string(fa.Addr)) } return fmt.Sprintf("%#x {Family: %s, Addr: %v, Port: %d}", addr, familyStr, fa.Addr, fa.Port) case linux.AF_NETLINK: sa, err := netlink.ExtractSockAddr(b) if err != nil { return fmt.Sprintf("%#x {Family: %s, error extracting address: %v}", addr, familyStr, err) } return fmt.Sprintf("%#x {Family: %s, PortID: %d, Groups: %d}", addr, familyStr, sa.PortID, sa.Groups) default: return fmt.Sprintf("%#x {Family: %s, family addr format unknown}", addr, familyStr) } } func postSockAddr(t *kernel.Task, addr hostarch.Addr, lengthPtr hostarch.Addr) string { if addr == 0 { return "null" } if lengthPtr == 0 { return fmt.Sprintf("%#x {length null}", addr) } l, err := copySockLen(t, lengthPtr) if err != nil { return fmt.Sprintf("%#x {error reading length: %v}", addr, err) } return sockAddr(t, addr, l) } func copySockLen(t *kernel.Task, addr hostarch.Addr) (uint32, error) { // socklen_t is 32-bits. var l primitive.Uint32 _, err := l.CopyIn(t, addr) return uint32(l), err } func sockLenPointer(t *kernel.Task, addr hostarch.Addr) string { if addr == 0 { return "null" } l, err := copySockLen(t, addr) if err != nil { return fmt.Sprintf("%#x {error reading length: %v}", addr, err) } return fmt.Sprintf("%#x {length=%v}", addr, l) } func sockType(stype int32) string { s := SocketType.Parse(uint64(stype & linux.SOCK_TYPE_MASK)) if flags := SocketFlagSet.Parse(uint64(stype &^ linux.SOCK_TYPE_MASK)); flags != "" { s += "|" + flags } return s } func sockProtocol(family, protocol int32) string { protocols, ok := SocketProtocol[family] if !ok { return fmt.Sprintf("%#x", protocol) } return protocols.Parse(uint64(protocol)) } func sockFlags(flags int32) string { if flags == 0 { return "0" } return SocketFlagSet.Parse(uint64(flags)) } func getSockOptVal(t *kernel.Task, level, optname uint64, optVal hostarch.Addr, optLen hostarch.Addr, maximumBlobSize uint, rval uintptr) string { if int(rval) < 0 { return hexNum(uint64(optVal)) } if optVal == 0 { return "null" } l, err := copySockLen(t, optLen) if err != nil { return fmt.Sprintf("%#x {error reading length: %v}", optLen, err) } return sockOptVal(t, level, optname, optVal, uint64(l), maximumBlobSize) } func sockOptVal(t *kernel.Task, level, optname uint64, optVal hostarch.Addr, optLen uint64, maximumBlobSize uint) string { switch optLen { case 1: var v primitive.Uint8 _, err := v.CopyIn(t, optVal) if err != nil { return fmt.Sprintf("%#x {error reading optval: %v}", optVal, err) } return fmt.Sprintf("%#x {value=%v}", optVal, v) case 2: var v primitive.Uint16 _, err := v.CopyIn(t, optVal) if err != nil { return fmt.Sprintf("%#x {error reading optval: %v}", optVal, err) } return fmt.Sprintf("%#x {value=%v}", optVal, v) case 4: var v primitive.Uint32 _, err := v.CopyIn(t, optVal) if err != nil { return fmt.Sprintf("%#x {error reading optval: %v}", optVal, err) } return fmt.Sprintf("%#x {value=%v}", optVal, v) default: return dump(t, optVal, uint(optLen), maximumBlobSize) } } var sockOptLevels = abi.ValueSet{ linux.SOL_IP: "SOL_IP", linux.SOL_SOCKET: "SOL_SOCKET", linux.SOL_TCP: "SOL_TCP", linux.SOL_UDP: "SOL_UDP", linux.SOL_IPV6: "SOL_IPV6", linux.SOL_ICMPV6: "SOL_ICMPV6", linux.SOL_RAW: "SOL_RAW", linux.SOL_PACKET: "SOL_PACKET", linux.SOL_NETLINK: "SOL_NETLINK", } var sockOptNames = map[uint64]abi.ValueSet{ linux.SOL_IP: { linux.IP_TTL: "IP_TTL", linux.IP_MULTICAST_TTL: "IP_MULTICAST_TTL", linux.IP_MULTICAST_IF: "IP_MULTICAST_IF", linux.IP_MULTICAST_LOOP: "IP_MULTICAST_LOOP", linux.IP_TOS: "IP_TOS", linux.IP_RECVTOS: "IP_RECVTOS", linux.IPT_SO_GET_INFO: "IPT_SO_GET_INFO", linux.IPT_SO_GET_ENTRIES: "IPT_SO_GET_ENTRIES", linux.IP_ADD_MEMBERSHIP: "IP_ADD_MEMBERSHIP", linux.IP_DROP_MEMBERSHIP: "IP_DROP_MEMBERSHIP", linux.MCAST_JOIN_GROUP: "MCAST_JOIN_GROUP", linux.IP_ADD_SOURCE_MEMBERSHIP: "IP_ADD_SOURCE_MEMBERSHIP", linux.IP_BIND_ADDRESS_NO_PORT: "IP_BIND_ADDRESS_NO_PORT", linux.IP_BLOCK_SOURCE: "IP_BLOCK_SOURCE", linux.IP_CHECKSUM: "IP_CHECKSUM", linux.IP_DROP_SOURCE_MEMBERSHIP: "IP_DROP_SOURCE_MEMBERSHIP", linux.IP_FREEBIND: "IP_FREEBIND", linux.IP_HDRINCL: "IP_HDRINCL", linux.IP_IPSEC_POLICY: "IP_IPSEC_POLICY", linux.IP_MINTTL: "IP_MINTTL", linux.IP_MSFILTER: "IP_MSFILTER", linux.IP_MTU_DISCOVER: "IP_MTU_DISCOVER", linux.IP_MULTICAST_ALL: "IP_MULTICAST_ALL", linux.IP_NODEFRAG: "IP_NODEFRAG", linux.IP_OPTIONS: "IP_OPTIONS", linux.IP_PASSSEC: "IP_PASSSEC", linux.IP_PKTINFO: "IP_PKTINFO", linux.IP_RECVERR: "IP_RECVERR", linux.IP_RECVFRAGSIZE: "IP_RECVFRAGSIZE", linux.IP_RECVOPTS: "IP_RECVOPTS", linux.IP_RECVORIGDSTADDR: "IP_RECVORIGDSTADDR", linux.IP_RECVTTL: "IP_RECVTTL", linux.IP_RETOPTS: "IP_RETOPTS", linux.IP_TRANSPARENT: "IP_TRANSPARENT", linux.IP_UNBLOCK_SOURCE: "IP_UNBLOCK_SOURCE", linux.IP_UNICAST_IF: "IP_UNICAST_IF", linux.IP_XFRM_POLICY: "IP_XFRM_POLICY", linux.MCAST_BLOCK_SOURCE: "MCAST_BLOCK_SOURCE", linux.MCAST_JOIN_SOURCE_GROUP: "MCAST_JOIN_SOURCE_GROUP", linux.MCAST_LEAVE_GROUP: "MCAST_LEAVE_GROUP", linux.MCAST_LEAVE_SOURCE_GROUP: "MCAST_LEAVE_SOURCE_GROUP", linux.MCAST_MSFILTER: "MCAST_MSFILTER", linux.MCAST_UNBLOCK_SOURCE: "MCAST_UNBLOCK_SOURCE", linux.IP_ROUTER_ALERT: "IP_ROUTER_ALERT", linux.IP_PKTOPTIONS: "IP_PKTOPTIONS", linux.IP_MTU: "IP_MTU", linux.SO_ORIGINAL_DST: "SO_ORIGINAL_DST", }, linux.SOL_SOCKET: { linux.SO_ERROR: "SO_ERROR", linux.SO_PEERCRED: "SO_PEERCRED", linux.SO_PASSCRED: "SO_PASSCRED", linux.SO_SNDBUF: "SO_SNDBUF", linux.SO_RCVBUF: "SO_RCVBUF", linux.SO_REUSEADDR: "SO_REUSEADDR", linux.SO_REUSEPORT: "SO_REUSEPORT", linux.SO_BINDTODEVICE: "SO_BINDTODEVICE", linux.SO_BROADCAST: "SO_BROADCAST", linux.SO_KEEPALIVE: "SO_KEEPALIVE", linux.SO_LINGER: "SO_LINGER", linux.SO_SNDTIMEO: "SO_SNDTIMEO", linux.SO_RCVTIMEO: "SO_RCVTIMEO", linux.SO_OOBINLINE: "SO_OOBINLINE", linux.SO_TIMESTAMP: "SO_TIMESTAMP", }, linux.SOL_TCP: { linux.TCP_NODELAY: "TCP_NODELAY", linux.TCP_CORK: "TCP_CORK", linux.TCP_QUICKACK: "TCP_QUICKACK", linux.TCP_MAXSEG: "TCP_MAXSEG", linux.TCP_KEEPIDLE: "TCP_KEEPIDLE", linux.TCP_KEEPINTVL: "TCP_KEEPINTVL", linux.TCP_USER_TIMEOUT: "TCP_USER_TIMEOUT", linux.TCP_INFO: "TCP_INFO", linux.TCP_CC_INFO: "TCP_CC_INFO", linux.TCP_NOTSENT_LOWAT: "TCP_NOTSENT_LOWAT", linux.TCP_ZEROCOPY_RECEIVE: "TCP_ZEROCOPY_RECEIVE", linux.TCP_CONGESTION: "TCP_CONGESTION", linux.TCP_LINGER2: "TCP_LINGER2", linux.TCP_DEFER_ACCEPT: "TCP_DEFER_ACCEPT", linux.TCP_REPAIR_OPTIONS: "TCP_REPAIR_OPTIONS", linux.TCP_INQ: "TCP_INQ", linux.TCP_FASTOPEN: "TCP_FASTOPEN", linux.TCP_FASTOPEN_CONNECT: "TCP_FASTOPEN_CONNECT", linux.TCP_FASTOPEN_KEY: "TCP_FASTOPEN_KEY", linux.TCP_FASTOPEN_NO_COOKIE: "TCP_FASTOPEN_NO_COOKIE", linux.TCP_KEEPCNT: "TCP_KEEPCNT", linux.TCP_QUEUE_SEQ: "TCP_QUEUE_SEQ", linux.TCP_REPAIR: "TCP_REPAIR", linux.TCP_REPAIR_QUEUE: "TCP_REPAIR_QUEUE", linux.TCP_REPAIR_WINDOW: "TCP_REPAIR_WINDOW", linux.TCP_SAVED_SYN: "TCP_SAVED_SYN", linux.TCP_SAVE_SYN: "TCP_SAVE_SYN", linux.TCP_SYNCNT: "TCP_SYNCNT", linux.TCP_THIN_DUPACK: "TCP_THIN_DUPACK", linux.TCP_THIN_LINEAR_TIMEOUTS: "TCP_THIN_LINEAR_TIMEOUTS", linux.TCP_TIMESTAMP: "TCP_TIMESTAMP", linux.TCP_ULP: "TCP_ULP", linux.TCP_WINDOW_CLAMP: "TCP_WINDOW_CLAMP", }, linux.SOL_IPV6: { linux.IPV6_V6ONLY: "IPV6_V6ONLY", linux.IPV6_PATHMTU: "IPV6_PATHMTU", linux.IPV6_TCLASS: "IPV6_TCLASS", linux.IPV6_ADD_MEMBERSHIP: "IPV6_ADD_MEMBERSHIP", linux.IPV6_DROP_MEMBERSHIP: "IPV6_DROP_MEMBERSHIP", linux.IPV6_IPSEC_POLICY: "IPV6_IPSEC_POLICY", linux.IPV6_JOIN_ANYCAST: "IPV6_JOIN_ANYCAST", linux.IPV6_LEAVE_ANYCAST: "IPV6_LEAVE_ANYCAST", linux.IPV6_PKTINFO: "IPV6_PKTINFO", linux.IPV6_ROUTER_ALERT: "IPV6_ROUTER_ALERT", linux.IPV6_XFRM_POLICY: "IPV6_XFRM_POLICY", linux.MCAST_BLOCK_SOURCE: "MCAST_BLOCK_SOURCE", linux.MCAST_JOIN_GROUP: "MCAST_JOIN_GROUP", linux.MCAST_JOIN_SOURCE_GROUP: "MCAST_JOIN_SOURCE_GROUP", linux.MCAST_LEAVE_GROUP: "MCAST_LEAVE_GROUP", linux.MCAST_LEAVE_SOURCE_GROUP: "MCAST_LEAVE_SOURCE_GROUP", linux.MCAST_UNBLOCK_SOURCE: "MCAST_UNBLOCK_SOURCE", linux.IPV6_2292DSTOPTS: "IPV6_2292DSTOPTS", linux.IPV6_2292HOPLIMIT: "IPV6_2292HOPLIMIT", linux.IPV6_2292HOPOPTS: "IPV6_2292HOPOPTS", linux.IPV6_2292PKTINFO: "IPV6_2292PKTINFO", linux.IPV6_2292PKTOPTIONS: "IPV6_2292PKTOPTIONS", linux.IPV6_2292RTHDR: "IPV6_2292RTHDR", linux.IPV6_ADDR_PREFERENCES: "IPV6_ADDR_PREFERENCES", linux.IPV6_AUTOFLOWLABEL: "IPV6_AUTOFLOWLABEL", linux.IPV6_DONTFRAG: "IPV6_DONTFRAG", linux.IPV6_DSTOPTS: "IPV6_DSTOPTS", linux.IPV6_FLOWINFO: "IPV6_FLOWINFO", linux.IPV6_FLOWINFO_SEND: "IPV6_FLOWINFO_SEND", linux.IPV6_FLOWLABEL_MGR: "IPV6_FLOWLABEL_MGR", linux.IPV6_FREEBIND: "IPV6_FREEBIND", linux.IPV6_HOPOPTS: "IPV6_HOPOPTS", linux.IPV6_MINHOPCOUNT: "IPV6_MINHOPCOUNT", linux.IPV6_MTU: "IPV6_MTU", linux.IPV6_MTU_DISCOVER: "IPV6_MTU_DISCOVER", linux.IPV6_MULTICAST_ALL: "IPV6_MULTICAST_ALL", linux.IPV6_MULTICAST_HOPS: "IPV6_MULTICAST_HOPS", linux.IPV6_MULTICAST_IF: "IPV6_MULTICAST_IF", linux.IPV6_MULTICAST_LOOP: "IPV6_MULTICAST_LOOP", linux.IPV6_RECVDSTOPTS: "IPV6_RECVDSTOPTS", linux.IPV6_RECVERR: "IPV6_RECVERR", linux.IPV6_RECVFRAGSIZE: "IPV6_RECVFRAGSIZE", linux.IPV6_RECVHOPLIMIT: "IPV6_RECVHOPLIMIT", linux.IPV6_RECVHOPOPTS: "IPV6_RECVHOPOPTS", linux.IPV6_RECVORIGDSTADDR: "IPV6_RECVORIGDSTADDR", linux.IPV6_RECVPATHMTU: "IPV6_RECVPATHMTU", linux.IPV6_RECVPKTINFO: "IPV6_RECVPKTINFO", linux.IPV6_RECVRTHDR: "IPV6_RECVRTHDR", linux.IPV6_RECVTCLASS: "IPV6_RECVTCLASS", linux.IPV6_RTHDR: "IPV6_RTHDR", linux.IPV6_RTHDRDSTOPTS: "IPV6_RTHDRDSTOPTS", linux.IPV6_TRANSPARENT: "IPV6_TRANSPARENT", linux.IPV6_UNICAST_HOPS: "IPV6_UNICAST_HOPS", linux.IPV6_UNICAST_IF: "IPV6_UNICAST_IF", linux.MCAST_MSFILTER: "MCAST_MSFILTER", linux.IPV6_ADDRFORM: "IPV6_ADDRFORM", linux.IP6T_SO_GET_INFO: "IP6T_SO_GET_INFO", linux.IP6T_SO_GET_ENTRIES: "IP6T_SO_GET_ENTRIES", }, linux.SOL_NETLINK: { linux.NETLINK_BROADCAST_ERROR: "NETLINK_BROADCAST_ERROR", linux.NETLINK_CAP_ACK: "NETLINK_CAP_ACK", linux.NETLINK_DUMP_STRICT_CHK: "NETLINK_DUMP_STRICT_CHK", linux.NETLINK_EXT_ACK: "NETLINK_EXT_ACK", linux.NETLINK_LIST_MEMBERSHIPS: "NETLINK_LIST_MEMBERSHIPS", linux.NETLINK_NO_ENOBUFS: "NETLINK_NO_ENOBUFS", linux.NETLINK_PKTINFO: "NETLINK_PKTINFO", }, }