#define _GNU_SOURCE #ifndef __linux__ #error "The package is linux only!" #endif #ifdef KERNEL_SPACE #error "The build aims to the kernel, not userspace" #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "config.h" #include "mangle.h" #include "args.h" pthread_mutex_t rawsocket_lock; int rawsocket = -2; static int open_socket(struct mnl_socket **_nl) { struct mnl_socket *nl = NULL; nl = mnl_socket_open(NETLINK_NETFILTER); if (nl == NULL) { perror("mnl_socket_open"); return -1; } if (mnl_socket_bind(nl, 0, MNL_SOCKET_AUTOPID) < 0) { perror("mnl_socket_bind"); mnl_socket_close(nl); return -1; } *_nl = nl; return 0; } static int close_socket(struct mnl_socket **_nl) { struct mnl_socket *nl = *_nl; if (nl == NULL) return 1; if (mnl_socket_close(nl) < 0) { perror("mnl_socket_close"); return -1; } *_nl = NULL; return 0; } static int open_raw_socket(void) { if (rawsocket != -2) { errno = EALREADY; perror("Raw socket is already opened"); return -1; } rawsocket = socket(AF_INET, SOCK_RAW, IPPROTO_RAW); if (rawsocket == -1) { perror("Unable to create raw socket"); return -1; } int mark = RAWSOCKET_MARK; if (setsockopt(rawsocket, SOL_SOCKET, SO_MARK, &mark, sizeof(mark)) < 0) { fprintf(stderr, "setsockopt(SO_MARK, %d) failed\n", mark); return -1; } int mst = pthread_mutex_init(&rawsocket_lock, NULL); if (mst) { fprintf(stderr, "Mutex err: %d\n", mst); close(rawsocket); errno = mst; return -1; } return rawsocket; } static int close_raw_socket(void) { if (rawsocket < 0) { errno = EALREADY; perror("Raw socket is not set"); return -1; } if (close(rawsocket)) { perror("Unable to close raw socket"); pthread_mutex_destroy(&rawsocket_lock); return -1; } pthread_mutex_destroy(&rawsocket_lock); rawsocket = -2; return 0; } static int send_raw_socket(const uint8_t *pkt, uint32_t pktlen) { int ret; if (pktlen > AVAILABLE_MTU) { if (config.verbose) printf("Split packet!\n"); uint8_t buff1[MNL_SOCKET_BUFFER_SIZE]; uint32_t buff1_size = MNL_SOCKET_BUFFER_SIZE; uint8_t buff2[MNL_SOCKET_BUFFER_SIZE]; uint32_t buff2_size = MNL_SOCKET_BUFFER_SIZE; switch (config.fragmentation_strategy) { case FRAG_STRAT_TCP: if ((ret = tcp4_frag(pkt, pktlen, AVAILABLE_MTU-128, buff1, &buff1_size, buff2, &buff2_size)) < 0) { errno = -ret; return ret; } break; case FRAG_STRAT_IP: if ((ret = ip4_frag(pkt, pktlen, AVAILABLE_MTU-128, buff1, &buff1_size, buff2, &buff2_size)) < 0) { errno = -ret; return ret; } break; default: errno = EINVAL; printf("send_raw_socket: Packet is too big but fragmentation is disabled!\n"); return -EINVAL; } int sent = 0; int status = send_raw_socket(buff1, buff1_size); if (status >= 0) sent += status; else { return status; } status = send_raw_socket(buff2, buff2_size); if (status >= 0) sent += status; else { return status; } return sent; } struct iphdr *iph; if ((ret = ip4_payload_split( (uint8_t *)pkt, pktlen, &iph, NULL, NULL, NULL)) < 0) { errno = -ret; return ret; } struct sockaddr_in daddr = { .sin_family = AF_INET, /* Always 0 for raw socket */ .sin_port = 0, .sin_addr = { .s_addr = iph->daddr } }; pthread_mutex_lock(&rawsocket_lock); int sent = sendto(rawsocket, pkt, pktlen, 0, (struct sockaddr *)&daddr, sizeof(daddr)); pthread_mutex_unlock(&rawsocket_lock); /* The function will return -errno on error as well as errno value set itself */ if (sent < 0) sent = -errno; return sent; } struct packet_data { uint32_t id; uint16_t hw_proto; uint8_t hook; void *payload; uint16_t payload_len; }; // Per-queue data. Passed to queue_cb. struct queue_data { struct mnl_socket **_nl; int queue_num; }; /** * Used to accept unsupported packets (GSOs) */ static int fallback_accept_packet(uint32_t id, struct queue_data qdata) { char buf[MNL_SOCKET_BUFFER_SIZE]; struct nlmsghdr *verdnlh; verdnlh = nfq_nlmsg_put(buf, NFQNL_MSG_VERDICT, qdata.queue_num); nfq_nlmsg_verdict_put(verdnlh, id, NF_ACCEPT); if (mnl_socket_sendto(*qdata._nl, verdnlh, verdnlh->nlmsg_len) < 0) { perror("mnl_socket_send"); return MNL_CB_ERROR; } return MNL_CB_OK; } struct dps_t { uint8_t *pkt; uint32_t pktlen; // Time for the packet in milliseconds uint32_t timer; }; // Note that the thread will automatically release dps_t and pkt_buff void *delay_packet_send_fn(void *data) { struct dps_t *dpdt = data; uint8_t *pkt = dpdt->pkt; uint32_t pktlen = dpdt->pktlen; usleep(dpdt->timer * 1000); int ret = send_raw_socket(pkt, pktlen); if (ret < 0) { errno = -ret; perror("send delayed raw packet"); } free(pkt); free(dpdt); return NULL; } void delay_packet_send(const unsigned char *data, unsigned int data_len, unsigned int delay_ms) { struct dps_t *dpdt = malloc(sizeof(struct dps_t)); dpdt->pkt = malloc(data_len); memcpy(dpdt->pkt, data, data_len); dpdt->pktlen = data_len; dpdt->timer = delay_ms; pthread_t thr; pthread_create(&thr, NULL, delay_packet_send_fn, dpdt); pthread_detach(thr); } static int queue_cb(const struct nlmsghdr *nlh, void *data) { char buf[MNL_SOCKET_BUFFER_SIZE]; struct queue_data *qdata = data; struct nfqnl_msg_packet_hdr *ph = NULL; struct nlattr *attr[NFQA_MAX+1] = {0}; struct packet_data packet = {0}; if (nfq_nlmsg_parse(nlh, attr) < 0) { perror("Attr parse"); return MNL_CB_ERROR; } if (attr[NFQA_PACKET_HDR] == NULL) { errno = ENODATA; perror("Metaheader not set"); return MNL_CB_ERROR; } ph = mnl_attr_get_payload(attr[NFQA_PACKET_HDR]); packet.id = ntohl(ph->packet_id); packet.hw_proto = ntohs(ph->hw_protocol); packet.hook = ph->hook; packet.payload_len = mnl_attr_get_payload_len(attr[NFQA_PAYLOAD]); packet.payload = mnl_attr_get_payload(attr[NFQA_PAYLOAD]); if (attr[NFQA_CAP_LEN] != NULL && ntohl(mnl_attr_get_u32(attr[NFQA_CAP_LEN])) != packet.payload_len) { fprintf(stderr, "The packet was truncated! Skip!\n"); return fallback_accept_packet(packet.id, *qdata); } if (attr[NFQA_MARK] != NULL) { // Skip packets sent by rawsocket to escape infinity loop. if ((ntohl(mnl_attr_get_u32(attr[NFQA_MARK])) & RAWSOCKET_MARK) == RAWSOCKET_MARK) { return fallback_accept_packet(packet.id, *qdata); } } struct nlmsghdr *verdnlh; verdnlh = nfq_nlmsg_put(buf, NFQNL_MSG_VERDICT, qdata->queue_num); int ret = process_packet(packet.payload, packet.payload_len); switch (ret) { case PKT_DROP: nfq_nlmsg_verdict_put(verdnlh, packet.id, NF_DROP); break; default: nfq_nlmsg_verdict_put(verdnlh, packet.id, NF_ACCEPT); break; } if (mnl_socket_sendto(*qdata->_nl, verdnlh, verdnlh->nlmsg_len) < 0) { perror("mnl_socket_send"); return MNL_CB_ERROR; } return MNL_CB_OK; } #define BUF_SIZE (0xffff + (MNL_SOCKET_BUFFER_SIZE / 2)) int init_queue(int queue_num) { struct mnl_socket *nl; if (open_socket(&nl)) { perror("Unable to open socket"); return -1; } uint32_t portid = mnl_socket_get_portid(nl); struct nlmsghdr *nlh; char buf[BUF_SIZE]; nlh = nfq_nlmsg_put(buf, NFQNL_MSG_CONFIG, queue_num); nfq_nlmsg_cfg_put_cmd(nlh, AF_INET, NFQNL_CFG_CMD_BIND); if (mnl_socket_sendto(nl, nlh, nlh->nlmsg_len) < 0) { perror("mnl_socket_send"); goto die; } nlh = nfq_nlmsg_put(buf, NFQNL_MSG_CONFIG, queue_num); nfq_nlmsg_cfg_put_params(nlh, NFQNL_COPY_PACKET, 0xffff); if (config.use_gso) { mnl_attr_put_u32(nlh, NFQA_CFG_FLAGS, htonl(NFQA_CFG_F_GSO)); mnl_attr_put_u32(nlh, NFQA_CFG_MASK, htonl(NFQA_CFG_F_GSO)); } if (mnl_socket_sendto(nl, nlh, nlh->nlmsg_len) < 0) { perror("mnl_socket_send"); goto die; } /* ENOBUFS is signalled to userspace when packets were lost * on kernel side. In most cases, userspace isn't interested * in this information, so turn it off. */ int ret = 1; mnl_socket_setsockopt(nl, NETLINK_NO_ENOBUFS, &ret, sizeof(int)); struct queue_data qdata = { ._nl = &nl, .queue_num = queue_num }; printf("Queue %d started\n", qdata.queue_num); while (1) { ret = mnl_socket_recvfrom(nl, buf, BUF_SIZE); if (ret == -1) { perror("mnl_socket_recvfrom"); continue; } ret = mnl_cb_run(buf, ret, 0, portid, queue_cb, &qdata); if (ret < 0) { perror("mnl_cb_run"); } } close_socket(&nl); return 0; die: close_socket(&nl); return -1; } // Per-queue config. Used to initialize a queue. Passed to wrapper struct queue_conf { uint16_t i; int queue_num; }; struct queue_res { int status; }; static struct queue_res defqres = {0}; static struct queue_res threads_reses[MAX_THREADS]; void *init_queue_wrapper(void *qdconf) { struct queue_conf *qconf = qdconf; struct queue_res *thres = threads_reses + qconf->i; thres->status = init_queue(qconf->queue_num); fprintf(stderr, "Thread %d exited with status %d\n", qconf->i, thres->status); return thres; } struct instance_config_t instance_config = { .send_raw_packet = send_raw_socket, .send_delayed_packet = delay_packet_send, }; int main(int argc, char *argv[]) { int ret; if ((ret = parse_args(argc, argv)) != 0) { if (ret < 0) { perror("Unable to parse args"); exit(EXIT_FAILURE); } exit(EXIT_SUCCESS); } switch (config.fragmentation_strategy) { case FRAG_STRAT_TCP: printf("Using TCP segmentation\n"); break; case FRAG_STRAT_IP: printf("Using IP fragmentation\n"); break; default: printf("SNI fragmentation is disabled\n"); break; } if (config.seg2_delay) { printf("Some outgoing googlevideo request segments will be delayed for %d ms as of seg2_delay define\n", config.seg2_delay); } if (config.fake_sni) { printf("Fake SNI will be sent before each target client hello\n"); } else { printf("Fake SNI is disabled\n"); } if (config.frag_sni_reverse) { printf("Fragmentation Client Hello will be reversed\n"); } if (config.frag_sni_faked) { printf("Fooling packets will be sent near the original Client Hello\n"); } if (config.fake_sni_seq_len > 1) { printf("Faking sequence of length %d will be built as fake sni\n", config.fake_sni_seq_len); } switch (config.faking_strategy) { case FAKE_STRAT_TTL: printf("TTL faking strategy will be used with TTL %d\n", config.faking_ttl); break; case FAKE_STRAT_ACK_SEQ: printf("Ack-Seq faking strategy will be used\n"); break; } if (config.use_gso) { printf("GSO is enabled\n"); } if (open_raw_socket() < 0) { perror("Unable to open raw socket"); exit(EXIT_FAILURE); } struct queue_res *qres = &defqres; if (config.threads == 1) { struct queue_conf tconf = { .i = 0, .queue_num = config.queue_start_num }; qres = init_queue_wrapper(&tconf); } else { printf("%d threads wil be used\n", config.threads); struct queue_conf thread_confs[MAX_THREADS]; pthread_t threads[MAX_THREADS]; for (int i = 0; i < config.threads; i++) { struct queue_conf *tconf = thread_confs + i; pthread_t *thr = threads + i; tconf->queue_num = config.queue_start_num + i; tconf->i = i; pthread_create(thr, NULL, init_queue_wrapper, tconf); } void *res; for (int i = 0; i < config.threads; i++) { pthread_join(threads[i], &res); qres = res; } } if (close_raw_socket() < 0) { perror("Unable to close raw socket"); exit(EXIT_FAILURE); } return qres->status; }