使用Netfilter进行数据包分析

#include <linux/init.h>
#include <linux/module.h>
#include <linux/skbuff.h>
#include <linux/ip.h>
#include <linux/netfilter.h>
#include <linux/netfilter_ipv4.h>

MODULE_LICENSE("GPL");

void analyzeIPHeader(struct iphdr* ip_hdr)
{
printk("***********IP Header***********\n");
printk("%30s:\t0x%02x\n", "Version",
ip_hdr->version);

printk("%30s:\t0x%02x (%u)\n", "Header Length(Bytes)",
ip_hdr->ihl,
ip_hdr->ihl);

printk("%30s:\t0x%02x\n", "Type of service",
ip_hdr->tos);

printk("%30s:\t0x%04x (%u)\n", "Total Length(Bytes)",
ip_hdr->tot_len,
ip_hdr->tot_len);

printk("%30s:\t0x%04x (%u)\n", "Identification",
ip_hdr->id,
ip_hdr->id);

printk("%30s:\t0x%04x (%u)\n", "Fragment Offset",
ip_hdr->frag_off,
ip_hdr->frag_off);

printk("%30s:\t0x%02x\n", "Time to live",
ip_hdr->ttl);

printk("%30s:\t0x%02x", "Protocol",
ip_hdr->protocol);


if (ip_hdr->protocol == 0x11)
{
printk(" [UDP]\n");
}
else if (ip_hdr->protocol == 0x06)
{
printk(" [TCP]\n");
}
else if (ip_hdr->protocol == 0x01)
{
printk(" [ICMP]\n");
}
else if (ip_hdr->protocol == 0x02)
{
printk(" [IGMP]\n");
}

printk("%30s:\t0x%04x\n", "Header Checksum (CRC)",
ip_hdr->check);

printk("%30s:\t%u:%u:%u:%u\n", "Source IP Address",
*(unsigned char*)(((unsigned char*)&ip_hdr->saddr) + 0),
*(unsigned char*)(((unsigned char*)&ip_hdr->saddr) + 1),
*(unsigned char*)(((unsigned char*)&ip_hdr->saddr) + 2),
*(unsigned char*)(((unsigned char*)&ip_hdr->saddr) + 3)
);

printk("%30s:\t%u:%u:%u:%u\n", "Destination IP Address",
*(unsigned char*)(((unsigned char*)&ip_hdr->daddr) + 0),
*(unsigned char*)(((unsigned char*)&ip_hdr->daddr) + 1),
*(unsigned char*)(((unsigned char*)&ip_hdr->daddr) + 2),
*(unsigned char*)(((unsigned char*)&ip_hdr->daddr) + 3)
);

}

unsigned int hook_func(unsigned int hooknum,
struct sk_buff *skb,
const struct net_device *in,
const struct net_device *out,
int (*okfn)(struct sk_buff *))
{
struct sk_buff *sb = skb;
struct iphdr *iph ;


if (sb != NULL)
{
iph = ip_hdr(sb);

// printk("sk_buff : 0x%08x ip_hdr : 0x%08x \n", sb, iph);
if (iph != NULL)
{
// printk("ip: %d:%d\n", iph->saddr, iph->daddr);
analyzeIPHeader(iph);
}
}

return NF_ACCEPT;
}


static struct nf_hook_ops hook_ops = {
.hook = hook_func,
.hooknum = NF_INET_PRE_ROUTING,
.pf = PF_INET,
.priority = NF_IP_PRI_FIRST,
};

static int pslist_init()
{
printk("###################################################################\n");

// analyzeRegisters();
// analyzeUMANode();
// analyzeProcesses();
// analyzePhysicalPages();
// analyzeTaskPgd();
// cpuidTest();
// netanalyze();
nf_register_hook(&hook_ops);
return 0;
}

static void pslist_exit()
{
nf_unregister_hook(&hook_ops);
printk("###################################################################\n");
}



module_init(pslist_init);
module_exit(pslist_exit);

结果如下:

[ 3026.194484] ***********IP Header***********
[ 3026.194487] Version: 0x04
[ 3026.194489] Header Length(Bytes): 0x05 (5)
[ 3026.194490] Type of service: 0x00
[ 3026.194491] Total Length(Bytes): 0x7c00 (31744)
[ 3026.194492] Identification: 0xdd24 (56612)
[ 3026.194493] Fragment Offset: 0x0000 (0)
[ 3026.194494] Time to live: 0x40
[ 3026.194494] Protocol: 0x11 [UDP]
[ 3026.194496] Header Checksum (CRC): 0x0f3e
[ 3026.194497] Source IP Address: 10:64:1:55
[ 3026.194498] Destination IP Address: 127:0:0:1
[ 3026.439485] ***********IP Header***********
[ 3026.439489] Version: 0x04
[ 3026.439490] Header Length(Bytes): 0x05 (5)
[ 3026.439491] Type of service: 0x00
[ 3026.439492] Total Length(Bytes): 0x2800 (10240)
[ 3026.439493] Identification: 0xde24 (56868)
[ 3026.439494] Fragment Offset: 0x0000 (0)
[ 3026.439495] Time to live: 0x40
[ 3026.439496] Protocol: 0x06 [TCP]
[ 3026.439497] Header Checksum (CRC): 0x5d03
[ 3026.439499] Source IP Address: 115:239:210:151
[ 3026.439500] Destination IP Address: 127:0:0:1
[ 3026.746484] ***********IP Header***********
[ 3026.746495] Version: 0x04
[ 3026.746503] Header Length(Bytes): 0x05 (5)
[ 3026.746504] Type of service: 0x00
[ 3026.746505] Total Length(Bytes): 0x2800 (10240)
[ 3026.746506] Identification: 0xdf24 (57124)
[ 3026.746507] Fragment Offset: 0x0000 (0)
[ 3026.746508] Time to live: 0x40
[ 3026.746509] Protocol: 0x06 [TCP]
[ 3026.746510] Header Checksum (CRC): 0x7b11
[ 3026.746511] Source IP Address: 180:149:131:210
[ 3026.746513] Destination IP Address: 127:0:0:1
[ 3028.557038] ***********IP Header***********
[ 3028.557042] Version: 0x04
[ 3028.557043] Header Length(Bytes): 0x05 (5)
[ 3028.557044] Type of service: 0x00
[ 3028.557045] Total Length(Bytes): 0x2800 (10240)
[ 3028.557046] Identification: 0xe024 (57380)
[ 3028.557047] Fragment Offset: 0x0000 (0)
[ 3028.557048] Time to live: 0x40
[ 3028.557049] Protocol: 0x06 [TCP]
[ 3028.557050] Header Checksum (CRC): 0x6329
[ 3028.557052] Source IP Address: 61:160:226:222
[ 3028.557053] Destination IP Address: 127:0:0:1
[ 3028.617738] ***********IP Header***********
[ 3028.617742] Version: 0x04
[ 3028.617743] Header Length(Bytes): 0x05 (5)
[ 3028.617744] Type of service: 0x00
[ 3028.617746] Total Length(Bytes): 0x2800 (10240)
[ 3028.617747] Identification: 0xe124 (57636)
[ 3028.617748] Fragment Offset: 0x0000 (0)
[ 3028.617749] Time to live: 0x40
[ 3028.617749] Protocol: 0x06 [TCP]
[ 3028.617751] Header Checksum (CRC): 0x74ca
[ 3028.617752] Source IP Address: 58:221:68:143
[ 3028.617753] Destination IP Address: 127:0:0:1
[ 3028.624231] ***********IP Header***********
[ 3028.624234] Version: 0x04
[ 3028.624235] Header Length(Bytes): 0x05 (5)
[ 3028.624236] Type of service: 0x00
[ 3028.624237] Total Length(Bytes): 0x2800 (10240)
[ 3028.624238] Identification: 0xe224 (57892)
[ 3028.624239] Fragment Offset: 0x0000 (0)
[ 3028.624240] Time to live: 0x40
[ 3028.624241] Protocol: 0x06 [TCP]
[ 3028.624243] Header Checksum (CRC): 0x6fef
[ 3028.624244] Source IP Address: 58:216:31:152
[ 3028.624245] Destination IP Address: 127:0:0:1
[ 3030.353175] ***********IP Header***********
[ 3030.353179] Version: 0x04
[ 3030.353180] Header Length(Bytes): 0x05 (5)
[ 3030.353181] Type of service: 0x00
[ 3030.353182] Total Length(Bytes): 0x2800 (10240)
[ 3030.353183] Identification: 0xe324 (58148)
[ 3030.353184] Fragment Offset: 0x0000 (0)
[ 3030.353185] Time to live: 0x40
[ 3030.353186] Protocol: 0x06 [TCP]
[ 3030.353187] Header Checksum (CRC): 0x6203
[ 3030.353188] Source IP Address: 115:239:210:141
[ 3030.353190] Destination IP Address: 127:0:0:1
[ 3030.353785] ***********IP Header***********
[ 3030.353787] Version: 0x04
[ 3030.353788] Header Length(Bytes): 0x05 (5)
[ 3030.353788] Type of service: 0x00
[ 3030.353790] Total Length(Bytes): 0x2800 (10240)
[ 3030.353790] Identification: 0xe424 (58404)
[ 3030.353791] Fragment Offset: 0x0000 (0)
[ 3030.353792] Time to live: 0x40
[ 3030.353793] Protocol: 0x06 [TCP]
[ 3030.353794] Header Checksum (CRC): 0x6103
[ 3030.353795] Source IP Address: 115:239:210:141
[ 3030.353797] Destination IP Address: 127:0:0:1
[ 3030.354357] ***********IP Header***********
[ 3030.354358] Version: 0x04
[ 3030.354359] Header Length(Bytes): 0x05 (5)
[ 3030.354360] Type of service: 0x00
[ 3030.354361] Total Length(Bytes): 0x2800 (10240)
[ 3030.354362] Identification: 0xe524 (58660)
[ 3030.354363] Fragment Offset: 0x0000 (0)
[ 3030.354364] Time to live: 0x40
[ 3030.354365] Protocol: 0x06 [TCP]
[ 3030.354366] Header Checksum (CRC): 0x6003
[ 3030.354367] Source IP Address: 115:239:210:141
[ 3030.354368] Destination IP Address: 127:0:0:1
[ 3030.682150] ***********IP Header***********
[ 3030.682154] Version: 0x04
[ 3030.682155] Header Length(Bytes): 0x05 (5)
[ 3030.682157] Type of service: 0x00
[ 3030.682158] Total Length(Bytes): 0x2800 (10240)
[ 3030.682159] Identification: 0xe624 (58916)
[ 3030.682160] Fragment Offset: 0x0000 (0)
[ 3030.682160] Time to live: 0x40
[ 3030.682161] Protocol: 0x06 [TCP]
[ 3030.682163] Header Checksum (CRC): 0x5f03
[ 3030.682164] Source IP Address: 115:239:210:141
[ 3030.682165] Destination IP Address: 127:0:0:1
[ 3035.425863] ###################################################################


为什么通过netfilter截获的sk_buff结构,无法通过其next域获取到整个的sk_buff列表?

这是因为,sk_buff列表是由网络接口层(以太网层)维护的,当有新的网络包传送过来,网卡会向CPU发出中断请求,CPU执行中断服务例程,将网卡上的内容读入到每个CPU特定的sk_buff列表中,这个列表就是我们所说的sk_buff列表。

为了尽快地执行完中断服务例程的Top Half,一旦将sk_buff保存到队列中,就马上返回。

上层的网络层可以根据需要从队列中拿出sk_buff进行处理,如果是发往本机的,就交给上层协议继续处理,如果是转发的,就再处理一下TTL,然后交给以太网层转发出去。

对于本机发往其他机器的sk_buff,通过各层协议,最终加入到CPU的sk_buff队列,然后交给以太网层传送出去。

 

image

通过上图可见,Netfilter处于的位置,都是在以太网层上面的,因此这时截获的sk_buff都是与队列无关,因此next域都是NULL。

否则的话,这应该也算是一个漏洞,因为相当于Netfilter就可以控制所有类型的sk_buff了,而不单单是它请求处理的类型。

posted @ 2014-01-21 17:34  Daniel King  阅读(1283)  评论(0编辑  收藏  举报