// Copyright 2019 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 proc import ( "bytes" "fmt" "io" "reflect" "time" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/log" "gvisor.dev/gvisor/pkg/sentry/fsimpl/kernfs" "gvisor.dev/gvisor/pkg/sentry/inet" "gvisor.dev/gvisor/pkg/sentry/kernel" "gvisor.dev/gvisor/pkg/sentry/kernel/auth" "gvisor.dev/gvisor/pkg/sentry/socket" "gvisor.dev/gvisor/pkg/sentry/socket/unix" "gvisor.dev/gvisor/pkg/sentry/socket/unix/transport" "gvisor.dev/gvisor/pkg/sentry/vfs" "gvisor.dev/gvisor/pkg/syserror" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/usermem" ) func (fs *filesystem) newTaskNetDir(task *kernel.Task) kernfs.Inode { k := task.Kernel() pidns := task.PIDNamespace() root := auth.NewRootCredentials(pidns.UserNamespace()) var contents map[string]kernfs.Inode if stack := task.NetworkNamespace().Stack(); stack != nil { const ( arp = "IP address HW type Flags HW address Mask Device\n" netlink = "sk Eth Pid Groups Rmem Wmem Dump Locks Drops Inode\n" packet = "sk RefCnt Type Proto Iface R Rmem User Inode\n" protocols = "protocol size sockets memory press maxhdr slab module cl co di ac io in de sh ss gs se re sp bi br ha uh gp em\n" ptype = "Type Device Function\n" upd6 = " sl local_address remote_address st tx_queue rx_queue tr tm->when retrnsmt uid timeout inode\n" ) psched := fmt.Sprintf("%08x %08x %08x %08x\n", uint64(time.Microsecond/time.Nanosecond), 64, 1000000, uint64(time.Second/time.Nanosecond)) // TODO(gvisor.dev/issue/1833): Make sure file contents reflect the task // network namespace. contents = map[string]kernfs.Inode{ "dev": fs.newInode(root, 0444, &netDevData{stack: stack}), "snmp": fs.newInode(root, 0444, &netSnmpData{stack: stack}), // The following files are simple stubs until they are implemented in // netstack, if the file contains a header the stub is just the header // otherwise it is an empty file. "arp": fs.newInode(root, 0444, newStaticFile(arp)), "netlink": fs.newInode(root, 0444, newStaticFile(netlink)), "netstat": fs.newInode(root, 0444, &netStatData{}), "packet": fs.newInode(root, 0444, newStaticFile(packet)), "protocols": fs.newInode(root, 0444, newStaticFile(protocols)), // Linux sets psched values to: nsec per usec, psched tick in ns, 1000000, // high res timer ticks per sec (ClockGetres returns 1ns resolution). "psched": fs.newInode(root, 0444, newStaticFile(psched)), "ptype": fs.newInode(root, 0444, newStaticFile(ptype)), "route": fs.newInode(root, 0444, &netRouteData{stack: stack}), "tcp": fs.newInode(root, 0444, &netTCPData{kernel: k}), "udp": fs.newInode(root, 0444, &netUDPData{kernel: k}), "unix": fs.newInode(root, 0444, &netUnixData{kernel: k}), } if stack.SupportsIPv6() { contents["if_inet6"] = fs.newInode(root, 0444, &ifinet6{stack: stack}) contents["ipv6_route"] = fs.newInode(root, 0444, newStaticFile("")) contents["tcp6"] = fs.newInode(root, 0444, &netTCP6Data{kernel: k}) contents["udp6"] = fs.newInode(root, 0444, newStaticFile(upd6)) } } return fs.newTaskOwnedDir(task, fs.NextIno(), 0555, contents) } // ifinet6 implements vfs.DynamicBytesSource for /proc/net/if_inet6. // // +stateify savable type ifinet6 struct { kernfs.DynamicBytesFile stack inet.Stack } var _ dynamicInode = (*ifinet6)(nil) func (n *ifinet6) contents() []string { var lines []string nics := n.stack.Interfaces() for id, naddrs := range n.stack.InterfaceAddrs() { nic, ok := nics[id] if !ok { // NIC was added after NICNames was called. We'll just ignore it. continue } for _, a := range naddrs { // IPv6 only. if a.Family != linux.AF_INET6 { continue } // Fields: // IPv6 address displayed in 32 hexadecimal chars without colons // Netlink device number (interface index) in hexadecimal (use nic id) // Prefix length in hexadecimal // Scope value (use 0) // Interface flags // Device name lines = append(lines, fmt.Sprintf("%032x %02x %02x %02x %02x %8s\n", a.Addr, id, a.PrefixLen, 0, a.Flags, nic.Name)) } } return lines } // Generate implements vfs.DynamicBytesSource.Generate. func (n *ifinet6) Generate(ctx context.Context, buf *bytes.Buffer) error { for _, l := range n.contents() { buf.WriteString(l) } return nil } // netDevData implements vfs.DynamicBytesSource for /proc/net/dev. // // +stateify savable type netDevData struct { kernfs.DynamicBytesFile stack inet.Stack } var _ dynamicInode = (*netDevData)(nil) // Generate implements vfs.DynamicBytesSource.Generate. func (n *netDevData) Generate(ctx context.Context, buf *bytes.Buffer) error { interfaces := n.stack.Interfaces() buf.WriteString("Inter-| Receive | Transmit\n") buf.WriteString(" face |bytes packets errs drop fifo frame compressed multicast|bytes packets errs drop fifo colls carrier compressed\n") for _, i := range interfaces { // Implements the same format as // net/core/net-procfs.c:dev_seq_printf_stats. var stats inet.StatDev if err := n.stack.Statistics(&stats, i.Name); err != nil { log.Warningf("Failed to retrieve interface statistics for %v: %v", i.Name, err) continue } fmt.Fprintf( buf, "%6s: %7d %7d %4d %4d %4d %5d %10d %9d %8d %7d %4d %4d %4d %5d %7d %10d\n", i.Name, // Received stats[0], // bytes stats[1], // packets stats[2], // errors stats[3], // dropped stats[4], // fifo stats[5], // frame stats[6], // compressed stats[7], // multicast // Transmitted stats[8], // bytes stats[9], // packets stats[10], // errors stats[11], // dropped stats[12], // fifo stats[13], // frame stats[14], // compressed stats[15], // multicast ) } return nil } // netUnixData implements vfs.DynamicBytesSource for /proc/net/unix. // // +stateify savable type netUnixData struct { kernfs.DynamicBytesFile kernel *kernel.Kernel } var _ dynamicInode = (*netUnixData)(nil) // Generate implements vfs.DynamicBytesSource.Generate. func (n *netUnixData) Generate(ctx context.Context, buf *bytes.Buffer) error { buf.WriteString("Num RefCount Protocol Flags Type St Inode Path\n") for _, se := range n.kernel.ListSockets() { s := se.SockVFS2 if !s.TryIncRef() { log.Debugf("Couldn't get reference on %v in socket table, racing with destruction?", s) continue } if family, _, _ := s.Impl().(socket.SocketVFS2).Type(); family != linux.AF_UNIX { s.DecRef(ctx) // Not a unix socket. continue } sops := s.Impl().(*unix.SocketVFS2) addr, err := sops.Endpoint().GetLocalAddress() if err != nil { log.Warningf("Failed to retrieve socket name from %+v: %v", s, err) addr.Addr = "" } sockFlags := 0 if ce, ok := sops.Endpoint().(transport.ConnectingEndpoint); ok { if ce.Listening() { // For unix domain sockets, linux reports a single flag // value if the socket is listening, of __SO_ACCEPTCON. sockFlags = linux.SO_ACCEPTCON } } // Get inode number. var ino uint64 stat, statErr := s.Stat(ctx, vfs.StatOptions{Mask: linux.STATX_INO}) if statErr != nil || stat.Mask&linux.STATX_INO == 0 { log.Warningf("Failed to retrieve ino for socket file: %v", statErr) } else { ino = stat.Ino } // In the socket entry below, the value for the 'Num' field requires // some consideration. Linux prints the address to the struct // unix_sock representing a socket in the kernel, but may redact the // value for unprivileged users depending on the kptr_restrict // sysctl. // // One use for this field is to allow a privileged user to // introspect into the kernel memory to determine information about // a socket not available through procfs, such as the socket's peer. // // In gvisor, returning a pointer to our internal structures would // be pointless, as it wouldn't match the memory layout for struct // unix_sock, making introspection difficult. We could populate a // struct unix_sock with the appropriate data, but even that // requires consideration for which kernel version to emulate, as // the definition of this struct changes over time. // // For now, we always redact this pointer. fmt.Fprintf(buf, "%#016p: %08X %08X %08X %04X %02X %8d", (*unix.SocketOperations)(nil), // Num, pointer to kernel socket struct. s.ReadRefs()-1, // RefCount, don't count our own ref. 0, // Protocol, always 0 for UDS. sockFlags, // Flags. sops.Endpoint().Type(), // Type. sops.State(), // State. ino, // Inode. ) // Path if len(addr.Addr) != 0 { if addr.Addr[0] == 0 { // Abstract path. fmt.Fprintf(buf, " @%s", string(addr.Addr[1:])) } else { fmt.Fprintf(buf, " %s", string(addr.Addr)) } } fmt.Fprintf(buf, "\n") s.DecRef(ctx) } return nil } func networkToHost16(n uint16) uint16 { // n is in network byte order, so is big-endian. The most-significant byte // should be stored in the lower address. // // We manually inline binary.BigEndian.Uint16() because Go does not support // non-primitive consts, so binary.BigEndian is a (mutable) var, so calls to // binary.BigEndian.Uint16() require a read of binary.BigEndian and an // interface method call, defeating inlining. buf := [2]byte{byte(n >> 8 & 0xff), byte(n & 0xff)} return usermem.ByteOrder.Uint16(buf[:]) } func writeInetAddr(w io.Writer, family int, i linux.SockAddr) { switch family { case linux.AF_INET: var a linux.SockAddrInet if i != nil { a = *i.(*linux.SockAddrInet) } // linux.SockAddrInet.Port is stored in the network byte order and is // printed like a number in host byte order. Note that all numbers in host // byte order are printed with the most-significant byte first when // formatted with %X. See get_tcp4_sock() and udp4_format_sock() in Linux. port := networkToHost16(a.Port) // linux.SockAddrInet.Addr is stored as a byte slice in big-endian order // (i.e. most-significant byte in index 0). Linux represents this as a // __be32 which is a typedef for an unsigned int, and is printed with // %X. This means that for a little-endian machine, Linux prints the // least-significant byte of the address first. To emulate this, we first // invert the byte order for the address using usermem.ByteOrder.Uint32, // which makes it have the equivalent encoding to a __be32 on a little // endian machine. Note that this operation is a no-op on a big endian // machine. Then similar to Linux, we format it with %X, which will print // the most-significant byte of the __be32 address first, which is now // actually the least-significant byte of the original address in // linux.SockAddrInet.Addr on little endian machines, due to the conversion. addr := usermem.ByteOrder.Uint32(a.Addr[:]) fmt.Fprintf(w, "%08X:%04X ", addr, port) case linux.AF_INET6: var a linux.SockAddrInet6 if i != nil { a = *i.(*linux.SockAddrInet6) } port := networkToHost16(a.Port) addr0 := usermem.ByteOrder.Uint32(a.Addr[0:4]) addr1 := usermem.ByteOrder.Uint32(a.Addr[4:8]) addr2 := usermem.ByteOrder.Uint32(a.Addr[8:12]) addr3 := usermem.ByteOrder.Uint32(a.Addr[12:16]) fmt.Fprintf(w, "%08X%08X%08X%08X:%04X ", addr0, addr1, addr2, addr3, port) } } func commonGenerateTCP(ctx context.Context, buf *bytes.Buffer, k *kernel.Kernel, family int) error { // t may be nil here if our caller is not part of a task goroutine. This can // happen for example if we're here for "sentryctl cat". When t is nil, // degrade gracefully and retrieve what we can. t := kernel.TaskFromContext(ctx) for _, se := range k.ListSockets() { s := se.SockVFS2 if !s.TryIncRef() { log.Debugf("Couldn't get reference on %v in socket table, racing with destruction?", s) continue } sops, ok := s.Impl().(socket.SocketVFS2) if !ok { panic(fmt.Sprintf("Found non-socket file in socket table: %+v", s)) } if fa, stype, _ := sops.Type(); !(family == fa && stype == linux.SOCK_STREAM) { s.DecRef(ctx) // Not tcp4 sockets. continue } // Linux's documentation for the fields below can be found at // https://www.kernel.org/doc/Documentation/networking/proc_net_tcp.txt. // For Linux's implementation, see net/ipv4/tcp_ipv4.c:get_tcp4_sock(). // Note that the header doesn't contain labels for all the fields. // Field: sl; entry number. fmt.Fprintf(buf, "%4d: ", se.ID) // Field: local_adddress. var localAddr linux.SockAddr if t != nil { if local, _, err := sops.GetSockName(t); err == nil { localAddr = local } } writeInetAddr(buf, family, localAddr) // Field: rem_address. var remoteAddr linux.SockAddr if t != nil { if remote, _, err := sops.GetPeerName(t); err == nil { remoteAddr = remote } } writeInetAddr(buf, family, remoteAddr) // Field: state; socket state. fmt.Fprintf(buf, "%02X ", sops.State()) // Field: tx_queue, rx_queue; number of packets in the transmit and // receive queue. Unimplemented. fmt.Fprintf(buf, "%08X:%08X ", 0, 0) // Field: tr, tm->when; timer active state and number of jiffies // until timer expires. Unimplemented. fmt.Fprintf(buf, "%02X:%08X ", 0, 0) // Field: retrnsmt; number of unrecovered RTO timeouts. // Unimplemented. fmt.Fprintf(buf, "%08X ", 0) stat, statErr := s.Stat(ctx, vfs.StatOptions{Mask: linux.STATX_UID | linux.STATX_INO}) // Field: uid. if statErr != nil || stat.Mask&linux.STATX_UID == 0 { log.Warningf("Failed to retrieve uid for socket file: %v", statErr) fmt.Fprintf(buf, "%5d ", 0) } else { creds := auth.CredentialsFromContext(ctx) fmt.Fprintf(buf, "%5d ", uint32(auth.KUID(stat.UID).In(creds.UserNamespace).OrOverflow())) } // Field: timeout; number of unanswered 0-window probes. // Unimplemented. fmt.Fprintf(buf, "%8d ", 0) // Field: inode. if statErr != nil || stat.Mask&linux.STATX_INO == 0 { log.Warningf("Failed to retrieve inode for socket file: %v", statErr) fmt.Fprintf(buf, "%8d ", 0) } else { fmt.Fprintf(buf, "%8d ", stat.Ino) } // Field: refcount. Don't count the ref we obtain while deferencing // the weakref to this socket. fmt.Fprintf(buf, "%d ", s.ReadRefs()-1) // Field: Socket struct address. Redacted due to the same reason as // the 'Num' field in /proc/net/unix, see netUnix.ReadSeqFileData. fmt.Fprintf(buf, "%#016p ", (*socket.Socket)(nil)) // Field: retransmit timeout. Unimplemented. fmt.Fprintf(buf, "%d ", 0) // Field: predicted tick of soft clock (delayed ACK control data). // Unimplemented. fmt.Fprintf(buf, "%d ", 0) // Field: (ack.quick<<1)|ack.pingpong, Unimplemented. fmt.Fprintf(buf, "%d ", 0) // Field: sending congestion window, Unimplemented. fmt.Fprintf(buf, "%d ", 0) // Field: Slow start size threshold, -1 if threshold >= 0xFFFF. // Unimplemented, report as large threshold. fmt.Fprintf(buf, "%d", -1) fmt.Fprintf(buf, "\n") s.DecRef(ctx) } return nil } // netTCPData implements vfs.DynamicBytesSource for /proc/net/tcp. // // +stateify savable type netTCPData struct { kernfs.DynamicBytesFile kernel *kernel.Kernel } var _ dynamicInode = (*netTCPData)(nil) func (d *netTCPData) Generate(ctx context.Context, buf *bytes.Buffer) error { buf.WriteString(" sl local_address rem_address st tx_queue rx_queue tr tm->when retrnsmt uid timeout inode \n") return commonGenerateTCP(ctx, buf, d.kernel, linux.AF_INET) } // netTCP6Data implements vfs.DynamicBytesSource for /proc/net/tcp6. // // +stateify savable type netTCP6Data struct { kernfs.DynamicBytesFile kernel *kernel.Kernel } var _ dynamicInode = (*netTCP6Data)(nil) func (d *netTCP6Data) Generate(ctx context.Context, buf *bytes.Buffer) error { buf.WriteString(" sl local_address remote_address st tx_queue rx_queue tr tm->when retrnsmt uid timeout inode\n") return commonGenerateTCP(ctx, buf, d.kernel, linux.AF_INET6) } // netUDPData implements vfs.DynamicBytesSource for /proc/net/udp. // // +stateify savable type netUDPData struct { kernfs.DynamicBytesFile kernel *kernel.Kernel } var _ dynamicInode = (*netUDPData)(nil) // Generate implements vfs.DynamicBytesSource.Generate. func (d *netUDPData) Generate(ctx context.Context, buf *bytes.Buffer) error { // t may be nil here if our caller is not part of a task goroutine. This can // happen for example if we're here for "sentryctl cat". When t is nil, // degrade gracefully and retrieve what we can. t := kernel.TaskFromContext(ctx) buf.WriteString(" sl local_address rem_address st tx_queue rx_queue tr tm->when retrnsmt uid timeout inode ref pointer drops \n") for _, se := range d.kernel.ListSockets() { s := se.SockVFS2 if !s.TryIncRef() { log.Debugf("Couldn't get reference on %v in socket table, racing with destruction?", s) continue } sops, ok := s.Impl().(socket.SocketVFS2) if !ok { panic(fmt.Sprintf("Found non-socket file in socket table: %+v", s)) } if family, stype, _ := sops.Type(); family != linux.AF_INET || stype != linux.SOCK_DGRAM { s.DecRef(ctx) // Not udp4 socket. continue } // For Linux's implementation, see net/ipv4/udp.c:udp4_format_sock(). // Field: sl; entry number. fmt.Fprintf(buf, "%5d: ", se.ID) // Field: local_adddress. var localAddr linux.SockAddrInet if t != nil { if local, _, err := sops.GetSockName(t); err == nil { localAddr = *local.(*linux.SockAddrInet) } } writeInetAddr(buf, linux.AF_INET, &localAddr) // Field: rem_address. var remoteAddr linux.SockAddrInet if t != nil { if remote, _, err := sops.GetPeerName(t); err == nil { remoteAddr = *remote.(*linux.SockAddrInet) } } writeInetAddr(buf, linux.AF_INET, &remoteAddr) // Field: state; socket state. fmt.Fprintf(buf, "%02X ", sops.State()) // Field: tx_queue, rx_queue; number of packets in the transmit and // receive queue. Unimplemented. fmt.Fprintf(buf, "%08X:%08X ", 0, 0) // Field: tr, tm->when. Always 0 for UDP. fmt.Fprintf(buf, "%02X:%08X ", 0, 0) // Field: retrnsmt. Always 0 for UDP. fmt.Fprintf(buf, "%08X ", 0) stat, statErr := s.Stat(ctx, vfs.StatOptions{Mask: linux.STATX_UID | linux.STATX_INO}) // Field: uid. if statErr != nil || stat.Mask&linux.STATX_UID == 0 { log.Warningf("Failed to retrieve uid for socket file: %v", statErr) fmt.Fprintf(buf, "%5d ", 0) } else { creds := auth.CredentialsFromContext(ctx) fmt.Fprintf(buf, "%5d ", uint32(auth.KUID(stat.UID).In(creds.UserNamespace).OrOverflow())) } // Field: timeout. Always 0 for UDP. fmt.Fprintf(buf, "%8d ", 0) // Field: inode. if statErr != nil || stat.Mask&linux.STATX_INO == 0 { log.Warningf("Failed to retrieve inode for socket file: %v", statErr) fmt.Fprintf(buf, "%8d ", 0) } else { fmt.Fprintf(buf, "%8d ", stat.Ino) } // Field: ref; reference count on the socket inode. Don't count the ref // we obtain while deferencing the weakref to this socket. fmt.Fprintf(buf, "%d ", s.ReadRefs()-1) // Field: Socket struct address. Redacted due to the same reason as // the 'Num' field in /proc/net/unix, see netUnix.ReadSeqFileData. fmt.Fprintf(buf, "%#016p ", (*socket.Socket)(nil)) // Field: drops; number of dropped packets. Unimplemented. fmt.Fprintf(buf, "%d", 0) fmt.Fprintf(buf, "\n") s.DecRef(ctx) } return nil } // netSnmpData implements vfs.DynamicBytesSource for /proc/net/snmp. // // +stateify savable type netSnmpData struct { kernfs.DynamicBytesFile stack inet.Stack } var _ dynamicInode = (*netSnmpData)(nil) // +stateify savable type snmpLine struct { prefix string header string } var snmp = []snmpLine{ { prefix: "Ip", header: "Forwarding DefaultTTL InReceives InHdrErrors InAddrErrors ForwDatagrams InUnknownProtos InDiscards InDelivers OutRequests OutDiscards OutNoRoutes ReasmTimeout ReasmReqds ReasmOKs ReasmFails FragOKs FragFails FragCreates", }, { prefix: "Icmp", header: "InMsgs InErrors InCsumErrors InDestUnreachs InTimeExcds InParmProbs InSrcQuenchs InRedirects InEchos InEchoReps InTimestamps InTimestampReps InAddrMasks InAddrMaskReps OutMsgs OutErrors OutDestUnreachs OutTimeExcds OutParmProbs OutSrcQuenchs OutRedirects OutEchos OutEchoReps OutTimestamps OutTimestampReps OutAddrMasks OutAddrMaskReps", }, { prefix: "IcmpMsg", }, { prefix: "Tcp", header: "RtoAlgorithm RtoMin RtoMax MaxConn ActiveOpens PassiveOpens AttemptFails EstabResets CurrEstab InSegs OutSegs RetransSegs InErrs OutRsts InCsumErrors", }, { prefix: "Udp", header: "InDatagrams NoPorts InErrors OutDatagrams RcvbufErrors SndbufErrors InCsumErrors IgnoredMulti", }, { prefix: "UdpLite", header: "InDatagrams NoPorts InErrors OutDatagrams RcvbufErrors SndbufErrors InCsumErrors IgnoredMulti", }, } func toSlice(a interface{}) []uint64 { v := reflect.Indirect(reflect.ValueOf(a)) return v.Slice(0, v.Len()).Interface().([]uint64) } func sprintSlice(s []uint64) string { if len(s) == 0 { return "" } r := fmt.Sprint(s) return r[1 : len(r)-1] // Remove "[]" introduced by fmt of slice. } // Generate implements vfs.DynamicBytesSource.Generate. func (d *netSnmpData) Generate(ctx context.Context, buf *bytes.Buffer) error { types := []interface{}{ &inet.StatSNMPIP{}, &inet.StatSNMPICMP{}, nil, // TODO(gvisor.dev/issue/628): Support IcmpMsg stats. &inet.StatSNMPTCP{}, &inet.StatSNMPUDP{}, &inet.StatSNMPUDPLite{}, } for i, stat := range types { line := snmp[i] if stat == nil { fmt.Fprintf(buf, "%s:\n", line.prefix) fmt.Fprintf(buf, "%s:\n", line.prefix) continue } if err := d.stack.Statistics(stat, line.prefix); err != nil { if err == syserror.EOPNOTSUPP { log.Infof("Failed to retrieve %s of /proc/net/snmp: %v", line.prefix, err) } else { log.Warningf("Failed to retrieve %s of /proc/net/snmp: %v", line.prefix, err) } } fmt.Fprintf(buf, "%s: %s\n", line.prefix, line.header) if line.prefix == "Tcp" { tcp := stat.(*inet.StatSNMPTCP) // "Tcp" needs special processing because MaxConn is signed. RFC 2012. fmt.Fprintf(buf, "%s: %s %d %s\n", line.prefix, sprintSlice(tcp[:3]), int64(tcp[3]), sprintSlice(tcp[4:])) } else { fmt.Fprintf(buf, "%s: %s\n", line.prefix, sprintSlice(toSlice(stat))) } } return nil } // netRouteData implements vfs.DynamicBytesSource for /proc/net/route. // // +stateify savable type netRouteData struct { kernfs.DynamicBytesFile stack inet.Stack } var _ dynamicInode = (*netRouteData)(nil) // Generate implements vfs.DynamicBytesSource.Generate. // See Linux's net/ipv4/fib_trie.c:fib_route_seq_show. func (d *netRouteData) Generate(ctx context.Context, buf *bytes.Buffer) error { fmt.Fprintf(buf, "%-127s\n", "Iface\tDestination\tGateway\tFlags\tRefCnt\tUse\tMetric\tMask\tMTU\tWindow\tIRTT") interfaces := d.stack.Interfaces() for _, rt := range d.stack.RouteTable() { // /proc/net/route only includes ipv4 routes. if rt.Family != linux.AF_INET { continue } // /proc/net/route does not include broadcast or multicast routes. if rt.Type == linux.RTN_BROADCAST || rt.Type == linux.RTN_MULTICAST { continue } iface, ok := interfaces[rt.OutputInterface] if !ok || iface.Name == "lo" { continue } var ( gw uint32 prefix uint32 flags = linux.RTF_UP ) if len(rt.GatewayAddr) == header.IPv4AddressSize { flags |= linux.RTF_GATEWAY gw = usermem.ByteOrder.Uint32(rt.GatewayAddr) } if len(rt.DstAddr) == header.IPv4AddressSize { prefix = usermem.ByteOrder.Uint32(rt.DstAddr) } l := fmt.Sprintf( "%s\t%08X\t%08X\t%04X\t%d\t%d\t%d\t%08X\t%d\t%d\t%d", iface.Name, prefix, gw, flags, 0, // RefCnt. 0, // Use. 0, // Metric. (uint32(1)<