youtubeUnblock/mangle.c
2024-12-06 13:45:50 +03:00

755 lines
17 KiB
C

#define _GNU_SOURCE
#include "types.h" // IWYU pragma: keep
#include "mangle.h"
#include "config.h"
#include "utils.h"
#include "quic.h"
#include "logging.h"
#include "tls.h"
#ifndef KERNEL_SPACE
#include <stdlib.h>
#endif
int process_packet(const uint8_t *raw_payload, uint32_t raw_payload_len) {
if (raw_payload_len > MAX_PACKET_SIZE) {
return PKT_ACCEPT;
}
const struct iphdr *iph;
const struct ip6_hdr *ip6h;
uint32_t iph_len;
const uint8_t *ip_payload;
uint32_t ip_payload_len;
int transport_proto = -1;
int ipver = netproto_version(raw_payload, raw_payload_len);
int ret;
lgtrace_start();
lgtrace_addp("IPv%d", ipver);
if (ipver == IP4VERSION) {
ret = ip4_payload_split((uint8_t *)raw_payload, raw_payload_len,
(struct iphdr **)&iph, &iph_len,
(uint8_t **)&ip_payload, &ip_payload_len);
if (ret < 0)
goto accept;
transport_proto = iph->protocol;
} else if (ipver == IP6VERSION && config.use_ipv6) {
ret = ip6_payload_split((uint8_t *)raw_payload, raw_payload_len,
(struct ip6_hdr **)&ip6h, &iph_len,
(uint8_t **)&ip_payload, &ip_payload_len);
if (ret < 0)
goto accept;
transport_proto = ip6h->ip6_nxt;
} else {
lgtracemsg("Unknown layer 3 protocol version: %d", ipver);
goto accept;
}
int verdict = PKT_CONTINUE;
if (transport_proto == IPPROTO_TCP)
lgtrace_addp("TCP");
else if (transport_proto == IPPROTO_UDP)
lgtrace_addp("UDP");
ITER_CONFIG_SECTIONS(section) {
lgtrace_addp("Section #%d", CONFIG_SECTION_NUMBER(section));
switch (transport_proto) {
case IPPROTO_TCP:
verdict = process_tcp_packet(section, raw_payload, raw_payload_len);
break;
case IPPROTO_UDP:
verdict = process_udp_packet(section, raw_payload, raw_payload_len);
break;
}
if (verdict == PKT_CONTINUE) {
lgtrace_addp("continue_flow");
continue;
}
goto ret_verdict;
}
accept:
verdict = PKT_ACCEPT;
ret_verdict:
switch (verdict) {
case PKT_ACCEPT:
lgtrace_addp("accept");
break;
case PKT_DROP:
lgtrace_addp("drop");
break;
default:
lgtrace_addp("unknow verdict: %d", verdict);
}
lgtrace_end();
return verdict;
}
int process_tcp_packet(const struct section_config_t *section, const uint8_t *raw_payload, uint32_t raw_payload_len) {
const void *ipxh;
uint32_t iph_len;
const struct tcphdr *tcph;
uint32_t tcph_len;
const uint8_t *data;
uint32_t dlen;
int ipxv = netproto_version(raw_payload, raw_payload_len);
int ret = tcp_payload_split((uint8_t *)raw_payload, raw_payload_len,
(void *)&ipxh, &iph_len,
(struct tcphdr **)&tcph, &tcph_len,
(uint8_t **)&data, &dlen);
if (ret < 0) {
goto accept;
}
if (tcph->syn && section->synfake) {
lgtrace_addp("TCP syn alter");
NETBUF_ALLOC(payload, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(payload)) {
lgerror(-ENOMEM, "Allocation error");
goto accept;
}
memcpy(payload, ipxh, iph_len);
memcpy(payload + iph_len, tcph, tcph_len);
uint32_t fake_len = section->fake_sni_pkt_sz;
if (section->synfake_len)
fake_len = min(section->synfake_len, fake_len);
memcpy(payload + iph_len + tcph_len, section->fake_sni_pkt, fake_len);
struct tcphdr *tcph = (struct tcphdr *)(payload + iph_len);
if (ipxv == IP4VERSION) {
struct iphdr *iph = (struct iphdr *)payload;
iph->tot_len = htons(iph_len + tcph_len + fake_len);
set_ip_checksum(payload, iph_len);
set_tcp_checksum(tcph, iph, iph_len);
} else if (ipxv == IP6VERSION) {
struct ip6_hdr *ip6h = (struct ip6_hdr *)payload;
ip6h->ip6_plen = ntohs(tcph_len + fake_len);
set_ip_checksum(ip6h, iph_len);
set_tcp_checksum(tcph, ip6h, iph_len);
}
ret = instance_config.send_raw_packet(payload, iph_len + tcph_len + fake_len);
if (ret < 0) {
lgerror(ret, "send_syn_altered");
NETBUF_FREE(payload);
goto accept;
}
NETBUF_FREE(payload);
goto drop;
}
if (tcph->syn) goto continue_flow;
struct tls_verdict vrd = analyze_tls_data(section, data, dlen);
lgtrace_addp("TLS analyzed");
if (vrd.sni_len != 0) {
lgtrace_addp("SNI detected: %.*s", vrd.sni_len, data + vrd.sni_offset);
}
if (vrd.target_sni) {
lgdebugmsg("Target SNI detected: %.*s", vrd.sni_len, data + vrd.sni_offset);
uint32_t payload_len = raw_payload_len;
NETBUF_ALLOC(payload, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(payload)) {
lgerror(-ENOMEM, "Allocation error");
goto accept;
}
memcpy(payload, raw_payload, raw_payload_len);
void *iph;
uint32_t iph_len;
struct tcphdr *tcph;
uint32_t tcph_len;
uint8_t *data;
uint32_t dlen;
int ret = tcp_payload_split(payload, payload_len,
&iph, &iph_len, &tcph, &tcph_len,
&data, &dlen);
if (ret < 0) {
lgerror(ret, "tcp_payload_split in targ_sni");
goto accept_lc;
}
if (section->fk_winsize) {
tcph->window = htons(section->fk_winsize);
set_tcp_checksum(tcph, iph, iph_len);
}
if (0) {
int delta = 2;
ret = seqovl_packet(payload, &payload_len, delta);
int ret = tcp_payload_split(payload, payload_len,
&iph, &iph_len, &tcph, &tcph_len,
&data, &dlen);
if (ret < 0) {
lgerror(ret, "seqovl_packet delta %d", delta);
}
}
if (dlen > 1480 && config.verbose) {
lgdebugmsg("WARNING! Client Hello packet is too big and may cause issues!");
}
if (section->fake_sni) {
post_fake_sni(args_default_fake_type(section), iph, iph_len, tcph, tcph_len);
}
size_t ipd_offset;
size_t mid_offset;
switch (section->fragmentation_strategy) {
case FRAG_STRAT_TCP: {
ipd_offset = vrd.sni_target_offset;
mid_offset = ipd_offset + vrd.sni_target_len / 2;
uint32_t poses[2];
int cnt = 0;
if (section->frag_sni_pos && dlen > section->frag_sni_pos) {
poses[cnt++] = section->frag_sni_pos;
}
if (section->frag_middle_sni) {
poses[cnt++] = mid_offset;
}
if (cnt > 1 && poses[0] > poses[1]) {
uint32_t tmp = poses[0];
poses[0] = poses[1];
poses[1] = tmp;
}
ret = send_tcp_frags(section, payload, payload_len, poses, cnt, 0);
if (ret < 0) {
lgerror(ret, "tcp4 send frags");
goto accept_lc;
}
goto drop_lc;
}
break;
case FRAG_STRAT_IP:
if (ipxv == IP4VERSION) {
ipd_offset = ((char *)data - (char *)tcph) + vrd.sni_target_offset;
mid_offset = ipd_offset + vrd.sni_target_len / 2;
mid_offset += 8 - mid_offset % 8;
uint32_t poses[2];
int cnt = 0;
if (section->frag_sni_pos && dlen > section->frag_sni_pos) {
poses[cnt] = section->frag_sni_pos + ((char *)data - (char *)tcph);
poses[cnt] += 8 - poses[cnt] % 8;
cnt++;
}
if (section->frag_middle_sni) {
poses[cnt++] = mid_offset;
}
if (cnt > 1 && poses[0] > poses[1]) {
uint32_t tmp = poses[0];
poses[0] = poses[1];
poses[1] = tmp;
}
ret = send_ip4_frags(section, payload, payload_len, poses, cnt, 0);
if (ret < 0) {
lgerror(ret, "ip4 send frags");
goto accept_lc;
}
goto drop_lc;
} else {
lginfo("WARNING: IP fragmentation is supported only for IPv4\n");
goto default_send;
}
default:
default_send:
ret = instance_config.send_raw_packet(payload, payload_len);
if (ret < 0) {
lgerror(ret, "raw pack send");
goto accept_lc;
}
goto drop_lc;
}
goto drop_lc;
accept_lc:
NETBUF_FREE(payload);
goto accept;
drop_lc:
NETBUF_FREE(payload);
goto drop;
}
continue_flow:
return PKT_CONTINUE;
accept:
return PKT_ACCEPT;
drop:
return PKT_DROP;
}
int process_udp_packet(const struct section_config_t *section, const uint8_t *pkt, uint32_t pktlen) {
const void *iph;
uint32_t iph_len;
const struct udphdr *udph;
const uint8_t *data;
uint32_t dlen;
int ipver = netproto_version(pkt, pktlen);
int ret = udp_payload_split((uint8_t *)pkt, pktlen,
(void **)&iph, &iph_len,
(struct udphdr **)&udph,
(uint8_t **)&data, &dlen);
if (ret < 0) {
lgtrace_addp("undefined");
goto accept;
}
if (dlen > 10 && config.verbose == VERBOSE_TRACE) {
char logging_buf[128];
char *bufpt = logging_buf;
bufpt += sprintf(bufpt, "UDP payload start: [ ");
for (int i = 0; i < 10; i++) {
bufpt += sprintf(bufpt, "%02x ", data[i]);
}
bufpt += sprintf(bufpt, "]");
lgtrace_addp("%s", logging_buf);
}
if (!detect_udp_filtered(section, pkt, pktlen))
goto continue_flow;
if (section->udp_mode == UDP_MODE_DROP)
goto drop;
else if (section->udp_mode == UDP_MODE_FAKE) {
for (int i = 0; i < section->udp_fake_seq_len; i++) {
NETBUF_ALLOC(fake_udp, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(fake_udp)) {
lgerror(-ENOMEM, "Allocation error");
return -ENOMEM;
}
uint32_t fsn_len = MAX_PACKET_SIZE;
struct udp_fake_type fake_type = {
.fake_len = section->udp_fake_len,
.strategy = {
.strategy = section->udp_faking_strategy,
},
};
ret = gen_fake_udp(fake_type, iph, iph_len, udph, fake_udp, &fsn_len);
if (ret < 0) {
lgerror(ret, "gen_fake_udp");
goto erret_lc;
}
lgtrace_addp("post fake udp #%d", i + 1);
ret = instance_config.send_raw_packet(fake_udp, fsn_len);
if (ret < 0) {
lgerror(ret, "send fake udp");
goto erret_lc;
}
NETBUF_FREE(fake_udp);
continue;
erret_lc:
NETBUF_FREE(fake_udp);
goto accept;
}
ret = instance_config.send_raw_packet(pkt, pktlen);
goto drop;
}
continue_flow:
return PKT_CONTINUE;
accept_quic:
accept:
return PKT_ACCEPT;
drop:
return PKT_DROP;
}
int send_ip4_frags(const struct section_config_t *section, const uint8_t *packet, uint32_t pktlen, const uint32_t *poses, uint32_t poses_sz, uint32_t dvs) {
if (poses_sz == 0) {
if (section->seg2_delay && ((dvs > 0) ^ section->frag_sni_reverse)) {
if (!instance_config.send_delayed_packet) {
return -EINVAL;
}
lgtrace_addp("Sent %d delayed for %d", pktlen, section->seg2_delay);
instance_config.send_delayed_packet(
packet, pktlen, section->seg2_delay);
return 0;
} else {
lgtrace_addp("Sent %d bytes", pktlen);
return instance_config.send_raw_packet(
packet, pktlen);
}
} else {
NETBUF_ALLOC(frag1, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(frag1)) {
lgerror(-ENOMEM, "Allocation error");
return -ENOMEM;
}
NETBUF_ALLOC(frag2, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(frag2)) {
lgerror(-ENOMEM, "Allocation error");
NETBUF_FREE(frag1);
return -ENOMEM;
}
NETBUF_ALLOC(fake_pad, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(fake_pad)) {
lgerror(-ENOMEM, "Allocation error");
NETBUF_FREE(frag1);
NETBUF_FREE(frag2);
return -ENOMEM;
}
uint32_t f1len = MAX_PACKET_SIZE;
uint32_t f2len = MAX_PACKET_SIZE;
uint32_t fake_pad_len = MAX_PACKET_SIZE;
int ret;
if (dvs > poses[0]) {
lgerror(-EINVAL, "send_frags: Recursive dvs(%d) is more than poses0(%d)", dvs, poses[0]);
ret = -EINVAL;
goto erret_lc;
}
uint32_t frag_pos = poses[0] - dvs;
frag_pos += 8 - frag_pos % 8;
ret = ip4_frag(packet, pktlen, frag_pos,
frag1, &f1len, frag2, &f2len);
if (ret < 0) {
lgerror(ret, "send_frags: frag: with context packet with size %d, position: %d, recursive dvs: %d", pktlen, poses[0], dvs);
goto erret_lc;
}
dvs += frag_pos;
if (section->frag_sni_reverse)
goto send_frag2;
send_frag1:
ret = send_ip4_frags(section, frag1, f1len, NULL, 0, 0);
if (ret < 0) {
goto erret_lc;
}
if (section->frag_sni_reverse)
goto out_lc;
send_fake:
/*
if (section->frag_sni_faked) {
ITER_FAKE_STRAT(section->faking_strategy, strategy) {
uint32_t iphfl;
fake_pad_len = f2len;
ret = ip4_payload_split(frag2, f2len, NULL, &iphfl, NULL, NULL);
if (ret < 0) {
lgerror("Invalid frag2", ret);
goto erret_lc;
}
memcpy(fake_pad, frag2, iphfl + sizeof(struct udphdr));
memset(fake_pad + iphfl + sizeof(struct udphdr), 0, f2len - iphfl - sizeof(struct udphdr));
((struct iphdr *)fake_pad)->tot_len = htons(fake_pad_len);
((struct iphdr *)fake_pad)->id = 1;
((struct iphdr *)fake_pad)->ttl = 8;
((struct iphdr *)fake_pad)->frag_off = 0;
ip4_set_checksum((struct iphdr*)fake_pad);
// *(struct udphdr *)(fake_pad + iphfl) = *(struct udphdr *)(frag2 + iphfl);
ret = send_ip4_frags(fake_pad, fake_pad_len, NULL, 0, 0);
if (ret < 0) {
goto erret_lc;
}
}
}
*/
if (section->frag_sni_reverse)
goto send_frag1;
send_frag2:
ret = send_ip4_frags(section, frag2, f2len, poses + 1, poses_sz - 1, dvs);
if (ret < 0) {
goto erret_lc;
}
if (section->frag_sni_reverse)
goto send_fake;
out_lc:
NETBUF_FREE(frag1);
NETBUF_FREE(frag2);
NETBUF_FREE(fake_pad);
goto out;
erret_lc:
NETBUF_FREE(frag1);
NETBUF_FREE(frag2);
NETBUF_FREE(fake_pad);
return ret;
}
out:
return 0;
}
int send_tcp_frags(const struct section_config_t *section, const uint8_t *packet, uint32_t pktlen, const uint32_t *poses, uint32_t poses_sz, uint32_t dvs) {
if (poses_sz == 0) {
if (section->seg2_delay && ((dvs > 0) ^ section->frag_sni_reverse)) {
if (!instance_config.send_delayed_packet) {
return -EINVAL;
}
instance_config.send_delayed_packet(
packet, pktlen, section->seg2_delay);
return 0;
} else {
lgtrace_addp("raw send packet of %d bytes with %d dvs", pktlen, dvs);
return instance_config.send_raw_packet(
packet, pktlen);
}
} else {
NETBUF_ALLOC(frag1, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(frag1)) {
lgerror(-ENOMEM, "Allocation error");
return -ENOMEM;
}
NETBUF_ALLOC(frag2, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(frag2)) {
lgerror(-ENOMEM, "Allocation error");
NETBUF_FREE(frag1);
return -ENOMEM;
}
uint32_t f1len = MAX_PACKET_SIZE;
uint32_t f2len = MAX_PACKET_SIZE;
int ret;
if (dvs > poses[0]) {
lgerror(-EINVAL, "send_frags: Recursive dvs(%d) is more than poses0(%d)", dvs, poses[0]);
ret = -EINVAL;
goto erret_lc;
}
ret = tcp_frag(packet, pktlen, poses[0] - dvs,
frag1, &f1len, frag2, &f2len);
lgtrace_addp("Packet split in %d bytes position of payload start, dvs: %d to two packets of %d and %d lengths", poses[0], dvs, f1len, f2len);
if (ret < 0) {
lgerror(ret, "send_frags: tcp_frag: with context packet with size %d, position: %d, recursive dvs: %d", pktlen, poses[0], dvs);
goto erret_lc;
}
dvs += poses[0];
if (section->frag_sni_reverse)
goto send_frag2;
send_frag1:
{
ret = send_tcp_frags(section, frag1, f1len, NULL, 0, 0);
if (ret < 0) {
goto erret_lc;
}
if (section->frag_sni_reverse)
goto out_lc;
}
send_fake:
if (section->frag_sni_faked) {
uint32_t iphfl, tcphfl;
void *iph;
struct tcphdr *tcph;
ret = tcp_payload_split(frag2, f2len, &iph, &iphfl, &tcph, &tcphfl, NULL, NULL);
struct fake_type f_type = args_default_fake_type(section);
if ((f_type.strategy.strategy & FAKE_STRAT_PAST_SEQ) == FAKE_STRAT_PAST_SEQ) {
f_type.strategy.strategy ^= FAKE_STRAT_PAST_SEQ;
f_type.strategy.strategy |= FAKE_STRAT_RAND_SEQ;
f_type.strategy.randseq_offset = dvs;
}
f_type.seg2delay = section->seg2_delay;
post_fake_sni(f_type, iph, iphfl, tcph, tcphfl);
}
if (section->frag_sni_reverse)
goto send_frag1;
send_frag2:
{
ret = send_tcp_frags(section, frag2, f2len, poses + 1, poses_sz - 1, dvs);
if (ret < 0) {
goto erret_lc;
}
if (section->frag_sni_reverse)
goto send_fake;
}
out_lc:
NETBUF_FREE(frag1);
NETBUF_FREE(frag2);
goto out;
erret_lc:
NETBUF_FREE(frag1);
NETBUF_FREE(frag2);
return ret;
}
out:
return 0;
}
int post_fake_sni(struct fake_type f_type,
const void *iph, unsigned int iph_len,
const struct tcphdr *tcph, unsigned int tcph_len) {
uint8_t rfsiph[128];
uint8_t rfstcph[60];
int ret;
int ipxv = netproto_version(iph, iph_len);
memcpy(rfsiph, iph, iph_len);
memcpy(rfstcph, tcph, tcph_len);
void *fsiph = (void *)rfsiph;
struct tcphdr *fstcph = (void *)rfstcph;
ITER_FAKE_STRAT(f_type.strategy.strategy, strategy) {
struct fake_type fake_seq_type = f_type;
fake_seq_type.strategy.strategy = strategy;
// one goes for default fake
for (int i = 0; i < fake_seq_type.sequence_len; i++) {
NETBUF_ALLOC(fake_sni, MAX_PACKET_SIZE);
if (!NETBUF_CHECK(fake_sni)) {
lgerror(-ENOMEM, "Allocation error");
return -ENOMEM;
}
uint32_t fsn_len = MAX_PACKET_SIZE;
ret = gen_fake_sni(
fake_seq_type,
fsiph, iph_len, fstcph, tcph_len,
fake_sni, &fsn_len);
if (ret < 0) {
lgerror(ret, "gen_fake_sni");
goto erret_lc;
}
lgtrace_addp("post fake sni #%d", i + 1);
if (f_type.seg2delay) {
ret = instance_config.send_delayed_packet(fake_sni, fsn_len, f_type.seg2delay);
} else {
ret = instance_config.send_raw_packet(fake_sni, fsn_len);
}
if (ret < 0) {
lgerror(ret, "send fake sni");
goto erret_lc;
}
uint32_t iph_len;
uint32_t tcph_len;
uint32_t plen;
ret = tcp_payload_split(
fake_sni, fsn_len,
&fsiph, &iph_len,
&fstcph, &tcph_len,
NULL, &plen);
if (ret < 0) {
lgtrace_addp("continue fake seq");
goto erret_lc;
}
if (!(strategy == FAKE_STRAT_PAST_SEQ ||
strategy == FAKE_STRAT_RAND_SEQ)) {
fstcph->seq = htonl(ntohl(fstcph->seq) + plen);
}
if (ipxv == IP4VERSION) {
((struct iphdr *)fsiph)->id = htons(ntohs(((struct iphdr *)fsiph)->id) + 1);
}
memcpy(rfsiph, fsiph, iph_len);
memcpy(rfstcph, fstcph, tcph_len);
fsiph = (void *)rfsiph;
fstcph = (void *)rfstcph;
NETBUF_FREE(fake_sni);
continue;
erret_lc:
NETBUF_FREE(fake_sni);
return ret;
}
}
return 0;
}