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Go 如何使用原始套接字捕获网卡流量

作者:文一路挖坑侠

为了减少对环境的依赖可以使用原始套接字捕获网卡流量,然后使用 gopacket 的协议解析功能,这样就省去了解析这部分的工作量,正确性也可以得到保证,同时 CGO 也可以关闭,这篇文章主要介绍了Go 使用原始套接字捕获网卡流量,需要的朋友可以参考下

Go 捕获网卡流量使用最多的库为 github.com/google/gopacket,需要依赖 libpcap 导致必须开启 CGO 才能够进行编译。

为了减少对环境的依赖可以使用原始套接字捕获网卡流量,然后使用 gopacket 的协议解析功能,这样就省去了解析这部分的工作量,正确性也可以得到保证,同时 CGO 也可以关闭。

cilium 里有一个原始套接字打开的测试用例:

// Both openRawSock and htons are available in
// https://github.com/cilium/ebpf/blob/master/example_sock_elf_test.go.
// MIT license.
func OpenRawSocket(index int) (int, error) {
	sock, err := syscall.Socket(syscall.AF_PACKET, syscall.SOCK_RAW|syscall.SOCK_NONBLOCK|syscall.SOCK_CLOEXEC, int(htons(syscall.ETH_P_ALL)))
	if err != nil {
		return 0, err
	}
	sll := syscall.SockaddrLinklayer{Ifindex: index, Protocol: htons(syscall.ETH_P_ALL)}
	if err := syscall.Bind(sock, &sll); err != nil {
		syscall.Close(sock)
		return 0, err
	}
	return sock, nil
}
// htons converts the unsigned short integer hostshort from host byte order to network byte order.
func htons(i uint16) uint16 {
	b := make([]byte, 2)
	binary.BigEndian.PutUint16(b, i)
	return *(*uint16)(unsafe.Pointer(&b[0]))
}

但是这个示例有一个问题,只能拿到本机流量。

捕获经过网桥的非本机流量

通过 tcpdump 是可以抓到经过网桥的转发流量的,我们使用 strace 对 tcpdump 进行跟踪分析

root@localhost:~# strace -f tcpdump -i b_2_0 arp -nne
...
socket(AF_PACKET, SOCK_RAW, htons(0 /* ETH_P_??? */)) = 4
ioctl(4, SIOCGIFINDEX, {ifr_name="lo", ifr_ifindex=1}) = 0
ioctl(4, SIOCGIFHWADDR, {ifr_name="b_2_0", ifr_hwaddr={sa_family=ARPHRD_ETHER, sa_data=4e:59:d6:32:f6:42}}) = 0
newfstatat(AT_FDCWD, "/sys/class/net/b_2_0/wireless", 0x7ffdf063bc50, 0) = -1 ENOENT (No such file or directory)
openat(AT_FDCWD, "/sys/class/net/b_2_0/dsa/tagging", O_RDONLY) = -1 ENOENT (No such file or directory)
ioctl(4, SIOCGIFINDEX, {ifr_name="b_2_0", ifr_ifindex=6053}) = 0
bind(4, {sa_family=AF_PACKET, sll_protocol=htons(0 /* ETH_P_??? */), sll_ifindex=if_nametoindex("b_2_0"), sll_hatype=ARPHRD_NETROM, sll_pkttype=PACKET_HOST, sll_halen=0}, 20) = 0
getsockopt(4, SOL_SOCKET, SO_ERROR, [0], [4]) = 0
setsockopt(4, SOL_PACKET, PACKET_ADD_MEMBERSHIP, {mr_ifindex=if_nametoindex("b_2_0"), mr_type=PACKET_MR_PROMISC, mr_alen=0, mr_address=4e:59:d6:32:f6:42}, 16) = 0
getsockopt(4, SOL_SOCKET, SO_BPF_EXTENSIONS, [64], [4]) = 0
mmap(NULL, 266240, PROT_READ|PROT_WRITE, MAP_PRIVATE|MAP_ANONYMOUS, -1, 0) = 0x7fec47cbe000

看到有一个 setsockopt(PACKET_MR_PROMISC) 设置,看起来是开启的混杂模式,查看资料看到这是一个针对套接字级别的混杂模式。

由于之前看过 suricata 的代码,看看它是怎么做的,直接在 suricata 的仓库里面搜索 PACKET_MR_PROMISC 关键字,出现代码

memset(&sock_params, 0, sizeof(sock_params));
sock_params.mr_type = PACKET_MR_PROMISC;
sock_params.mr_ifindex = bind_address.sll_ifindex;
r = setsockopt(ptv->socket, SOL_PACKET, PACKET_ADD_MEMBERSHIP,(void *)&sock_params, sizeof(sock_params));
if (r < 0) {
    SCLogError("%s: failed to set promisc mode: %s", devname, strerror(errno));
    goto socket_err;
}

套接字设置混杂模式的 Go 实现如下

// Set socket level PROMISC mode
err = unix.SetsockoptPacketMreq(sock, syscall.SOL_PACKET, syscall.PACKET_ADD_MEMBERSHIP, &unix.PacketMreq{Type: unix.PACKET_MR_PROMISC, Ifindex: int32(index)})
if err != nil {
	syscall.Close(sock)
	return 0, err
}

捕获 VLAN 流量

目前只能拿到普通的以太网流量,如果还需要拿到 VLAN Id 的话,需要设置 PACKET_AUXDATA,参考 man packet

PACKET_AUXDATA (since Linux 2.6.21)
    If this binary option is enabled, the packet socket passes
    a metadata structure along with each packet in the
    recvmsg(2) control field.  The structure can be read with
    cmsg(3).  It is defined as
       struct tpacket_auxdata {
           __u32 tp_status;
           __u32 tp_len;      /* packet length */
           __u32 tp_snaplen;  /* captured length */
           __u16 tp_mac;
           __u16 tp_net;
           __u16 tp_vlan_tci;
           __u16 tp_vlan_tpid; /* Since Linux 3.14; earlier, these
                                  were unused padding bytes */
       };

Go 的实现如下

// Enable PACKET_AUXDATA option for VLAN
if err := syscall.SetsockoptInt(sock, syscall.SOL_PACKET, unix.PACKET_AUXDATA, 1); err != nil {
	syscall.Close(sock)
	return 0, err
}

完整的 OpenRawSocket 实现

完整的实现如下

func OpenRawSocket(index int) (int, error) {
	sock, err := syscall.Socket(syscall.AF_PACKET, syscall.SOCK_RAW|syscall.SOCK_NONBLOCK|syscall.SOCK_CLOEXEC, int(htons(syscall.ETH_P_ALL)))
	if err != nil {
		return 0, err
	}
	// Enable PACKET_AUXDATA option for VLAN
	if err := syscall.SetsockoptInt(sock, syscall.SOL_PACKET, unix.PACKET_AUXDATA, 1); err != nil {
		syscall.Close(sock)
		return 0, err
	}
	// Set socket level PROMISC mode
	err = unix.SetsockoptPacketMreq(sock, syscall.SOL_PACKET, syscall.PACKET_ADD_MEMBERSHIP, &unix.PacketMreq{Type: unix.PACKET_MR_PROMISC, Ifindex: int32(index)})
	if err != nil {
		syscall.Close(sock)
		return 0, err
	}
	sll := syscall.SockaddrLinklayer{Ifindex: index, Protocol: htons(syscall.ETH_P_ALL)}
	if err := syscall.Bind(sock, &sll); err != nil {
		syscall.Close(sock)
		return 0, err
	}
	return sock, nil
}

从 fd 中读取数据

这里使用 select(2) 简单地对 fd 进行监听,使用 recvmsg(2) 来读取数据,包括 VLAN tag。

实现如下

package pcap
import (
	"context"
	"syscall"
)
func FD_SET(fd int, p *syscall.FdSet) {	p.Bits[fd/64] |= 1 << (uint(fd) % 64) }
func FD_CLR(fd int, p *syscall.FdSet) {	p.Bits[fd/64] &^= 1 << (uint(fd) % 64) }
func FD_ISSET(fd int, p *syscall.FdSet) bool {	return p.Bits[fd/64]&(1<<(uint(fd)%64)) != 0 }
func FD_ZERO(p *syscall.FdSet) {
	for i := range p.Bits {
		p.Bits[i] = 0
	}
}
type RecvmsgHandler func(buf []byte, n int, oob []byte, oobn int, err error) error
func RecvmsgLoop(ctx context.Context, sockfd int, fn RecvmsgHandler) error {
	buf := make([]byte, 1024*64)
	oob := make([]byte, syscall.CmsgSpace(1024))
	readfds := syscall.FdSet{}
	for {
		select {
		case <-ctx.Done():
			return ctx.Err()
		default:
		}
		FD_ZERO(&readfds)
		FD_SET(sockfd, &readfds)
		tv := syscall.Timeval{Sec: 0, Usec: 100000} // 100ms
		nfds, err := syscall.Select(sockfd+1, &readfds, nil, nil, &tv)
		if err != nil {
			continue
		}
		if nfds > 0 && FD_ISSET(sockfd, &readfds) {
			n, oobn, _, _, err := syscall.Recvmsg(sockfd, buf, oob, 0)
			err = fn(buf, n, oob, oobn, err)
			if err != nil {
				return err
			}
		}
	}
}

VLAN 数据的解析逻辑如下

func decodeVlanIdByAuxData(oob []byte) (uint16, error) {
	msgs, err := syscall.ParseSocketControlMessage(oob)
	if err != nil {
		return 0, err
	}
	for _, m := range msgs {
		if m.Header.Level == syscall.SOL_PACKET && m.Header.Type == 8 && len(m.Data) >= 20 {
			auxdata := unix.TpacketAuxdata{
				Status:   binary.LittleEndian.Uint32(m.Data[0:4]),
				Vlan_tci: binary.LittleEndian.Uint16(m.Data[16:18]),
			}
			if auxdata.Status&unix.TP_STATUS_VLAN_VALID != 0 {
				return auxdata.Vlan_tci, nil
			}
		}
	}
	return 0, nil
}

总结

以上代码都在实际的场景中使用,只是稍微修改了一点细节以及使用 epoll(2) 来监听,结合 sync.Pool 和精简了解析逻辑,性能尚可能够满足要求。

参考

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