sad/udp2raw
1
0
Fork 0
mirror of https://github.com/wangyu-/udp2raw.git synced 2024-06-25 00:19:06 +00:00
Code Issues Packages Projects Releases Wiki Activity

Compare commits

base: sad:20200715.0
Branches Tags
sad:unified
sad:revert-455-unified
sad:master
sad:modify
sad:mp
sad:core_fix
sad:20230206.0
sad:20200818.0
sad:20200727.0
sad:20200715.0
sad:20190716.test.0
sad:20181113.0
sad:20180830.2
sad:20180830.1
sad:20180830.0
sad:20180728.1
sad:20180728.0
sad:20180225.0
sad:20180225.1
sad:20180220.1
sad:20180220.0
sad:20180111.1
sad:20180111.0
sad:20171125.0
sad:20171123.1
sad:20171111.0
sad:20171108.0
sad:20171103.0
sad:20171024.0
sad:20170918.0
sad:20170917.0
sad:20170911.0
sad:20170910.0
sad:20170906.0
sad:20170826.0
sad:20170821.0
sad:20170818.1
sad:20170818.0
sad:20170815.0
sad:20170813.1
sad:20170813.0
sad:20170811.0
sad:20170809.0
sad:20170808.0
sad:20170805.1
sad:20170805
...
compare: sad:unified
Branches Tags
sad:unified
sad:revert-455-unified
sad:master
sad:modify
sad:mp
sad:core_fix
sad:20230206.0
sad:20200818.0
sad:20200727.0
sad:20200715.0
sad:20190716.test.0
sad:20181113.0
sad:20180830.2
sad:20180830.1
sad:20180830.0
sad:20180728.1
sad:20180728.0
sad:20180225.0
sad:20180225.1
sad:20180220.1
sad:20180220.0
sad:20180111.1
sad:20180111.0
sad:20171125.0
sad:20171123.1
sad:20171111.0
sad:20171108.0
sad:20171103.0
sad:20171024.0
sad:20170918.0
sad:20170917.0
sad:20170911.0
sad:20170910.0
sad:20170906.0
sad:20170826.0
sad:20170821.0
sad:20170818.1
sad:20170818.0
sad:20170815.0
sad:20170813.1
sad:20170813.0
sad:20170811.0
sad:20170809.0
sad:20170808.0
sad:20170805.1
sad:20170805

36 Commits
20200715.0 ... unified

Author SHA1 Message Date
yancey
4623f878e0 fix cipher bug 2024-06-10 05:22:12 -04:00
Yancey Wang
e42f0e5732
Update README.md 2023-11-15 15:15:46 -05:00
yancey
f49e6adedf remove Dockerfile 2023-11-06 03:19:46 -05:00
yancey
d1a9bcc4fb try to fix linux 6.5 compile 2023-10-07 08:26:10 -04:00
Yancey Wang
bc8bd8c2f8
Merge pull request #475 from gek64/unified 
Fix compile errors on FreeBSD/pfSense/OPNsense
 2023-09-21 16:35:45 -04:00
gek64
ca16c3a5e6
Merge branch 'wangyu-:unified' into unified 2023-07-27 21:10:28 +08:00
Yancey Wang
7abe19c7d9
Merge pull request #482 from wangyu-/revert-455-unified 
Revert "fix CMakeLists.txt"
 2023-07-22 17:31:10 -04:00
Yancey Wang
f3f528e866
Revert "fix CMakeLists.txt" 2023-07-22 17:30:56 -04:00
Yancey Wang
ec6fad552b
Merge pull request #455 from HiGarfield/unified 
fix CMakeLists.txt
 2023-07-22 17:09:53 -04:00
yancey
87b878a09e fix stack-use-after-scope reported by sanitizer 2023-07-22 14:31:17 -04:00
yancey
e66eddd1d5 fix mem access problem reported by sanitizer 2023-07-22 14:00:03 -04:00
gek64
ec416515f3
Fix compile errors on freebsd 2023-06-14 16:26:10 +08:00
Yancey Wang
d12e540830
Update CMakeLists.txt 2023-06-04 21:44:44 -04:00
Yancey Wang
e7eecc8ef2
Update ISSUE_TEMPLATE.md 2023-05-10 00:08:00 -04:00
HiGarfield
82ba4f7d1b fix CMakeLists.txt 2023-02-09 01:23:51 +08:00
yancey
e5ecd33ec4 add .clang-format 2023-02-07 07:12:02 -05:00
yancey
9217e0e9e6 fix indent with clang-format 2023-02-07 07:11:49 -05:00
yancey
87b0db8862 add cmake 2023-02-07 07:02:13 -05:00
Yancey Wang
8ceaf27eda
Merge pull request #409 from brlin-tw/patch-2 
fix typo (stabilization)
 2022-01-26 00:59:47 -05:00
Yancey Wang
9f9e8caff6
Merge pull request #408 from brlin-tw/patch-1 
fix typo (facktcp -> faketcp)
 2022-01-26 00:59:25 -05:00
Yancey Wang
74f3eb90a7
Update README.md 2021-12-09 09:26:32 -05:00
林博仁(Buo-ren, Lin)
38286d5c5b
fix typo (stabilization) 
Signed-off-by: 林博仁(Buo-ren, Lin) <Buo.Ren.Lin@gmail.com>
 2021-09-14 00:54:21 +08:00
林博仁(Buo-ren, Lin)
ec849322d7
fix typo (facktcp -> faketcp) 
Signed-off-by: 林博仁(Buo-ren, Lin) <Buo.Ren.Lin@gmail.com>
 2021-09-14 00:34:07 +08:00
wangyu
b98a467eed fix source argument is the same as destination 2021-03-11 00:45:26 -05:00
wangyu
25d3323427 fix mp compile; fix tcp option bug 2021-02-17 16:58:32 -05:00
wangyu
b8e9095135 add --fix-gro reminder 2021-01-11 05:58:31 -05:00
wangyu
026f97687a fix packet_header->caplen <= max_data_len in network.cpp 2021-01-09 05:10:12 -05:00
wangyu-
f2f90a9a15
Update ISSUE_TEMPLATE.md 2020-09-20 05:16:05 -04:00
wangyu-
cf23f4d656
Update ISSUE_TEMPLATE.md 2020-09-20 05:12:33 -04:00
wangyu
59819db2dd do not quit when got pcap error 2020-08-27 00:32:07 -04:00
wangyu
cc6ea766c4 update makefile 2020-08-18 03:19:18 -04:00
wangyu
509156fc14 change toochain for arm x86 x64 2020-08-17 19:48:23 -04:00
wangyu
cb9059bf3b update readme.md 2020-08-17 18:26:20 -04:00
wangyu
07e2e695a6 put version.txt into release_mp 2020-07-27 11:33:26 -04:00
root
e8daf7c263 more fix of memory access 2020-07-26 19:07:17 +00:00
root
5f907e32d7 fix bad memorry access 2020-07-26 18:15:27 +00:00
28 changed files with 7673 additions and 9028 deletions
Show Stats Expand all files Collapse all files

4
.clang-format Normal file
View File

@ -0,0 +1,4 @@
SortIncludes: false
BasedOnStyle: Google
ColumnLimit: 0
IndentWidth: 4

35
CMakeLists.txt Normal file
View File

@ -0,0 +1,35 @@
#note: experimental
# currently only used for generating `compile_commands.json` for clangd.
# to build this project, it's suggested to use `makefile` instead
cmake_minimum_required(VERSION 3.7)
project(udp2raw)
set(CMAKE_EXPORT_COMPILE_COMMANDS ON)
set(CMAKE_CXX_STANDARD 11)
set(SOURCE_FILES
main.cpp
lib/md5.cpp
lib/pbkdf2-sha1.cpp
lib/pbkdf2-sha256.cpp
encrypt.cpp
log.cpp
network.cpp
common.cpp
connection.cpp
misc.cpp
fd_manager.cpp
client.cpp
server.cpp
lib/aes_faster_c/aes.cpp
lib/aes_faster_c/wrapper.cpp
my_ev.cpp
)
set(CMAKE_CXX_FLAGS "-Wall -Wextra -Wno-unused-variable -Wno-unused-parameter -Wno-missing-field-initializers -O2 -g -fsanitize=address,undefined")
add_executable(udp2raw ${SOURCE_FILES})
target_link_libraries(udp2raw rt)
target_link_libraries(udp2raw pthread)
include_directories(SYSTEM "libev")
include_directories(".")

13
Dockerfile
View File

@ -1,13 +0,0 @@
FROM alpine:3.6 as builder
WORKDIR /
RUN apk add --no-cache git build-base linux-headers && \
git clone https://github.com/wangyu-/udp2raw-tunnel.git && \
cd udp2raw-tunnel && \
make dynamic
FROM alpine:3.6
RUN apk add --no-cache libstdc++ iptables
COPY --from=builder /udp2raw-tunnel/udp2raw_dynamic /bin/
ENTRYPOINT [ "/bin/udp2raw_dynamic" ]

7
ISSUE_TEMPLATE.md
View File

@ -1,6 +1 @@
For English speaking user
https://github.com/wangyu-/UDPspeeder/wiki/Issue-Guide
中文用户请看:
https://github.com/wangyu-/UDPspeeder/wiki/发Issue前请看
(否则Issue可能被忽略或被直接关掉)
English Only.

91
README.md
View File

@ -1,42 +1,44 @@
# Udp2raw-tunnel
A Tunnel which turns UDP Traffic into Encrypted FakeTCP/UDP/ICMP Traffic by using Raw Socket, helps you Bypass UDP FireWalls(or Unstable UDP Environment). It can defend Replay-Attack and supports Multiplexing. It also acts as a Connection Stabilizer.
![image0](images/image0.PNG)
A Tunnel which turns UDP Traffic into Encrypted FakeTCP/UDP/ICMP Traffic by using Raw Socket, helps you Bypass UDP FireWalls(or Unstable UDP Environment).
When used alone,udp2raw tunnels only UDP traffic. Nevertheless,if you used udp2raw + any UDP-based VPN together,you can tunnel any traffic(include TCP/UDP/ICMP),currently OpenVPN/L2TP/ShadowVPN and [tinyfecVPN](https://github.com/wangyu-/tinyfecVPN) are confirmed to be supported.
![image_vpn](images/udp2rawopenvpn.PNG)
[简体中文](/doc/README.zh-cn.md)(内容更丰富)
![image0](images/image0.PNG)
or
![image_vpn](images/udp2rawopenvpn.PNG)
[udp2raw wiki](https://github.com/wangyu-/udp2raw-tunnel/wiki)
[简体中文](/doc/README.zh-cn.md)
# Support Platforms
Linux host (including desktop Linux,Android phone/tablet,OpenWRT router,or Raspberry PI) with root access.
Linux host (including desktop Linux,Android phone/tablet,OpenWRT router,or Raspberry PI) with root account or cap_net_raw capability.
For Windows and MacOS users, use the udp2raw in [this repo](https://github.com/wangyu-/udp2raw-multiplatform).
<del>For Windows and MacOS You can run udp2raw inside [this](https://github.com/wangyu-/udp2raw-tunnel/releases/download/20171108.0/lede-17.01.2-x86_virtual_machine_image.zip) 7.5mb virtual machine image(make sure network adapter runs at bridged mode).</del>
# Features
### Send/Receive UDP Packets with ICMP/FakeTCP/UDP headers
ICMP/FakeTCP headers help you bypass UDP blocking, UDP QOS or improper UDP NAT behavior on some ISPs. In ICMP header mode,udp2raw works like an ICMP tunnel.
UDP headers are also supported. In UDP header mode, it behaves just like a normal UDP tunnel, and you can just make use of the other features (such as encryption, anti-replay, or connection stalization).
UDP headers are also supported. In UDP header mode, it behaves just like a normal UDP tunnel, and you can just make use of the other features (such as encryption, anti-replay, or connection stabilization).
### Simulated TCP with Real-time/Out-of-Order Delivery
In FakeTCP header mode,udp2raw simulates 3-way handshake while establishing a connection,simulates seq and ack_seq while data transferring. It also simulates following TCP options: `MSS`, `sackOk`, `TS`, `TS_ack`, `wscale`.Firewalls will regard FakeTCP as a TCP connection, but its essentially UDP: it supports real-time/out-of-order delivery(just as normal UDP does), no congestion control or re-transmission. So there wont be any TCP over TCP problem when using OpenVPN.
In FakeTCP header mode,udp2raw simulates 3-way handshake while establishing a connection,simulates seq and ack_seq while data transferring. It also simulates a few TCP options such as: `MSS`, `sackOk`, `TS`, `TS_ack`, `wscale`. Firewalls will regard FakeTCP as a TCP connection, but its essentially UDP: it supports real-time/out-of-order delivery(just as normal UDP does), no congestion control or re-transmission. So there wont be any TCP over TCP problem when using OpenVPN.
### Encryption, Anti-Replay
* Encrypt your traffic with AES-128-CBC.
* Protect data integrity by HMAC-SHA1 (or weaker MD5/CRC32).
* Defense replay attack with an anti-replay window, smiliar to IPSec and OpenVPN.
* Defense replay attack with anti-replay window.
### Failure Dectection & Stablization (Connection Recovery)
[Notes on encryption](https://github.com/wangyu-/udp2raw-tunnel/wiki/Notes-on-encryption)
### Failure Dectection & Stabilization (Connection Recovery)
Conection failures are detected by heartbeats. If timed-out, client will automatically change port number and reconnect. If reconnection is successful, the previous connection will be recovered, and all existing UDP conversations will stay vaild.
For example, if you use udp2raw + OpenVPN, OpenVPN won't lose connection after any reconnect, **even if network cable is re-plugged or WiFi access point is changed**.
@ -79,9 +81,9 @@ Assume your UDP is blocked or being QOS-ed or just poorly supported. Assume your
Now,an encrypted raw tunnel has been established between client and server through TCP port 4096. Connecting to UDP port 3333 at the client side is equivalent to connecting to port 7777 at the server side. No UDP traffic will be exposed.
### Note
To run on Android, check [Android_Guide](/doc/android_guide.md)
To run on Android, check [Android_Guide](https://github.com/wangyu-/udp2raw/wiki/Android-Guide)
`-a` option automatically adds an iptables rule (or a few iptables rules) for you, udp2raw relys on this iptables rule to work stably. Be aware you dont forget `-a` (its a common mistake). If you dont want udp2raw to add iptables rule automatically, you can add it manually(take a look at `-g` option) and omit `-a`.
`-a` option automatically adds an iptables rule (or a few iptables rules) for you, udp2raw relies on this iptables rule to work stably. Be aware you dont forget `-a` (its a common mistake). If you dont want udp2raw to add iptables rule automatically, you can add it manually(take a look at `-g` option) and omit `-a`.
# Advanced Topic
@ -218,63 +220,6 @@ raw_mode: faketcp cipher_mode: aes128cbc  auth_mode: md5
(reverse speed was simliar and not uploaded)
# Application
## Tunneling any traffic via raw traffic by using udp2raw +openvpn
![image_vpn](images/udp2rawopenvpn.PNG)
1. Bypasses UDP block/UDP QOS
2. No TCP over TCP problem (TCP over TCP problem http://sites.inka.de/bigred/devel/tcp-tcp.html ,https://community.openvpn.net/openvpn/ticket/2 )
3. OpenVpn over ICMP also becomes a choice
4. Supports almost any UDP-based VPN
More details at [openvpn+udp2raw_guide](https://github.com/wangyu-/udp2raw-tunnel/wiki/udp2raw-openvpn-config-guide)
## Speed-up tcp connection via raw traffic by using udp2raw+kcptun
kcptun is a tcp connection speed-up program,it speeds-up tcp connection by using kcp protocol on-top of udp.by using udp2raw,you can use kcptun while udp is QoSed or blocked.
(kcptun, https://github.com/xtaci/kcptun)
## Speed-up tcp connection via raw traffic by using udp2raw+finalspeed
finalspeed is a tcp connection speed-up program similiar to kcptun,it speeds-up tcp connection by using kcp protocol on-top of udp or tcp.but its tcp mode doesnt support openvz,you can bypass this problem if you use udp2raw+finalspeed together,and icmp mode also becomes avaliable.
# How to build
read [build_guide](/doc/build_guide.md)
# Other
### Easier installation on ArchLinux
```
yaourt -S udp2raw-tunnel # or
pacaur -S udp2raw-tunnel
```
# Related work
### kcptun-raw
udp2raw was inspired by kcptun-raw,which modified kcptun to support tcp mode.
https://github.com/Chion82/kcptun-raw
### relayRawSocket
kcptun-raw was inspired by relayRawSocket. A simple udp to raw tunnel,wrote in python
https://github.com/linhua55/some_kcptun_tools/tree/master/relayRawSocket
### kcpraw
another project of kcptun with tcp mode
https://github.com/ccsexyz/kcpraw
### icmptunnel
Transparently tunnel your IP traffic through ICMP echo and reply packets.
https://github.com/DhavalKapil/icmptunnel
### Tcp Minion
Tcp Minion is a project which modifid the code of tcp stack in kernel,and implemented real-time out-order udp packet delivery through this modified tcp stack.I failed to find the implementation,but there are some papers avaliable:
https://arxiv.org/abs/1103.0463
http://korz.cs.yale.edu/2009/tng/papers/pfldnet10.pdf
https://pdfs.semanticscholar.org/9e6f/e2306f4385b4eb5416d1fcab16e9361d6ba3.pdf
# wiki
Check wiki for more info:

453
client.cpp
View File

@ -14,7 +14,6 @@ u64_t laste_detect_time=0;
int use_udp_for_detection = 0;
int use_tcp_for_detection = 1;
extern pcap_t *pcap_handle;
extern int pcap_captured_full_len;
@ -34,15 +33,10 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
#ifdef UDP2RAW_MP
// mylog(log_debug,"pcap cnt :%d\n",pcap_cnt);
if(send_with_pcap&&!pcap_header_captured)
{
if(get_current_time()-laste_detect_time>detect_interval)
{
if (send_with_pcap && !pcap_header_captured) {
if (get_current_time() - laste_detect_time > detect_interval) {
laste_detect_time = get_current_time();
}
else
{
} else {
return 0;
}
/*
@ -57,11 +51,9 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
address_t tmp_addr = remote_addr;
tmp_addr.set_port(port);
if(use_udp_for_detection)
{
if (use_udp_for_detection) {
int new_udp_fd = socket(tmp_addr.get_type(), SOCK_DGRAM, IPPROTO_UDP);
if(new_udp_fd<0)
{
if (new_udp_fd < 0) {
mylog(log_warn, "create new_udp_fd error\n");
return -1;
}
@ -69,20 +61,17 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
u64_t tmp = get_true_random_number();
int ret = sendto(new_udp_fd, (char *)(&tmp), sizeof(tmp), 0, (struct sockaddr *)&tmp_addr.inner, tmp_addr.get_len());
if(ret==-1)
{
if (ret == -1) {
mylog(log_warn, "sendto() failed\n");
}
sock_close(new_udp_fd);
}
if(use_tcp_for_detection)
{
if (use_tcp_for_detection) {
static int last_tcp_fd = -1;
int new_tcp_fd = socket(tmp_addr.get_type(), SOCK_STREAM, IPPROTO_TCP);
if(new_tcp_fd<0)
{
if (new_tcp_fd < 0) {
mylog(log_warn, "create new_tcp_fd error\n");
return -1;
}
@ -94,29 +83,24 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
// close(new_tcp_fd);
}
mylog(log_info, "waiting for a use-able packet to be captured\n");
return 0;
}
#endif
if(raw_info.disabled)
{
if (raw_info.disabled) {
conn_info.state.client_current_state = client_idle;
conn_info.my_id = get_true_random_number_nz();
mylog(log_info, "state back to client_idle\n");
}
if(conn_info.state.client_current_state==client_idle)
{
if (conn_info.state.client_current_state == client_idle) {
raw_info.rst_received = 0;
raw_info.disabled = 0;
fail_time_counter++;
if(max_fail_time>0&&fail_time_counter>max_fail_time)
{
if (max_fail_time > 0 && fail_time_counter > max_fail_time) {
mylog(log_fatal, "max_fail_time exceed\n");
myexit(-1);
}
@ -124,14 +108,10 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
conn_info.blob->anti_replay.re_init();
conn_info.my_id = get_true_random_number_nz(); /// todo no need to do this everytime
address_t tmp_addr;
// u32_t new_ip=0;
if(!force_source_ip)
{
if(get_src_adress2(tmp_addr,remote_addr)!=0)
{
if (!force_source_ip) {
if (get_src_adress2(tmp_addr, remote_addr) != 0) {
mylog(log_warn, "get_src_adress() failed\n");
return -1;
}
@ -149,55 +129,42 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
send_info.src_ip=new_ip;
}*/
}
else
{
} else {
tmp_addr = source_addr;
}
send_info.new_src_ip.from_address_t(tmp_addr);
if (force_source_port == 0)
{
if (force_source_port == 0) {
send_info.src_port = client_bind_to_a_new_port2(bind_fd, tmp_addr);
}
else
{
} else {
send_info.src_port = source_port;
}
if (raw_mode == mode_icmp)
{
if (raw_mode == mode_icmp) {
send_info.dst_port = send_info.src_port;
}
mylog(log_info, "using port %d\n", send_info.src_port);
init_filter(send_info.src_port);
if(raw_mode==mode_icmp||raw_mode==mode_udp)
{
if (raw_mode == mode_icmp || raw_mode == mode_udp) {
conn_info.state.client_current_state = client_handshake1;
mylog(log_info, "state changed from client_idle to client_pre_handshake\n");
}
if(raw_mode==mode_faketcp)
{
if(use_tcp_dummy_socket)
{
if (raw_mode == mode_faketcp) {
if (use_tcp_dummy_socket) {
setnonblocking(bind_fd);
int ret = connect(bind_fd, (struct sockaddr *)&remote_addr.inner, remote_addr.get_len());
mylog(log_debug, "ret=%d,errno=%s, %d %s\n", ret, get_sock_error(), bind_fd, remote_addr.get_str());
// mylog(log_info,"ret=%d,errno=,%d %s\n",ret,bind_fd,remote_addr.get_str());
conn_info.state.client_current_state = client_tcp_handshake_dummy;
mylog(log_info, "state changed from client_idle to client_tcp_handshake_dummy\n");
}
else
{
} else {
conn_info.state.client_current_state = client_tcp_handshake;
mylog(log_info, "state changed from client_idle to client_tcp_handshake\n");
}
}
conn_info.last_state_time = get_current_time();
conn_info.last_hb_sent_time = 0;
@ -206,20 +173,14 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
if (conn_info.state.client_current_state == client_tcp_handshake) // send and resend syn
{
assert(raw_mode == mode_faketcp);
if (get_current_time() - conn_info.last_state_time > client_handshake_timeout)
{
if (get_current_time() - conn_info.last_state_time > client_handshake_timeout) {
conn_info.state.client_current_state = client_idle;
mylog(log_info, "state back to client_idle from client_tcp_handshake\n");
return 0;
}
else if (get_current_time() - conn_info.last_hb_sent_time > client_retry_interval)
{
if (raw_mode == mode_faketcp)
{
if (conn_info.last_hb_sent_time == 0)
{
} else if (get_current_time() - conn_info.last_hb_sent_time > client_retry_interval) {
if (raw_mode == mode_faketcp) {
if (conn_info.last_hb_sent_time == 0) {
send_info.psh = 0;
send_info.syn = 1;
send_info.ack = 0;
@ -234,40 +195,27 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
conn_info.last_hb_sent_time = get_current_time();
mylog(log_info, "(re)sent tcp syn\n");
return 0;
}
else
{
} else {
return 0;
}
return 0;
}
else if(conn_info.state.client_current_state==client_tcp_handshake_dummy)
{
} else if (conn_info.state.client_current_state == client_tcp_handshake_dummy) {
assert(raw_mode == mode_faketcp);
if (get_current_time() - conn_info.last_state_time > client_handshake_timeout)
{
if (get_current_time() - conn_info.last_state_time > client_handshake_timeout) {
conn_info.state.client_current_state = client_idle;
mylog(log_info, "state back to client_idle from client_tcp_handshake_dummy\n");
return 0;
}
}
else if(conn_info.state.client_current_state==client_handshake1)//send and resend handshake1
{
if(get_current_time()-conn_info.last_state_time>client_handshake_timeout)
} else if (conn_info.state.client_current_state == client_handshake1) // send and resend handshake1
{
if (get_current_time() - conn_info.last_state_time > client_handshake_timeout) {
conn_info.state.client_current_state = client_idle;
mylog(log_info, "state back to client_idle from client_handshake1\n");
return 0;
}
else if(get_current_time()-conn_info.last_hb_sent_time>client_retry_interval)
{
if(raw_mode==mode_faketcp)
{
if(conn_info.last_hb_sent_time==0)
{
} else if (get_current_time() - conn_info.last_hb_sent_time > client_retry_interval) {
if (raw_mode == mode_faketcp) {
if (conn_info.last_hb_sent_time == 0) {
send_info.seq++;
send_info.ack_seq = recv_info.seq + 1;
send_info.ts_ack = recv_info.ts;
@ -284,10 +232,7 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
send_handshake(raw_info, conn_info.my_id, 0, const_id);
send_info.seq += raw_info.send_info.data_len;
}
else
{
} else {
send_handshake(raw_info, conn_info.my_id, 0, const_id);
if (raw_mode == mode_icmp)
send_info.my_icmp_seq++;
@ -296,27 +241,18 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
conn_info.last_hb_sent_time = get_current_time();
mylog(log_info, "(re)sent handshake1\n");
return 0;
}
else
{
} else {
return 0;
}
return 0;
}
else if(conn_info.state.client_current_state==client_handshake2)
{
if(get_current_time()-conn_info.last_state_time>client_handshake_timeout)
{
} else if (conn_info.state.client_current_state == client_handshake2) {
if (get_current_time() - conn_info.last_state_time > client_handshake_timeout) {
conn_info.state.client_current_state = client_idle;
mylog(log_info, "state back to client_idle from client_handshake2\n");
return 0;
}
else if(get_current_time()-conn_info.last_hb_sent_time>client_retry_interval)
{
if(raw_mode==mode_faketcp)
{
if(conn_info.last_hb_sent_time==0)
{
} else if (get_current_time() - conn_info.last_hb_sent_time > client_retry_interval) {
if (raw_mode == mode_faketcp) {
if (conn_info.last_hb_sent_time == 0) {
send_info.ack_seq = recv_info.seq + raw_info.recv_info.data_len;
send_info.ts_ack = recv_info.ts;
raw_info.reserved_send_seq = send_info.seq;
@ -325,10 +261,7 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
send_handshake(raw_info, conn_info.my_id, conn_info.oppsite_id, const_id);
send_info.seq += raw_info.send_info.data_len;
}
else
{
} else {
send_handshake(raw_info, conn_info.my_id, conn_info.oppsite_id, const_id);
if (raw_mode == mode_icmp)
send_info.my_icmp_seq++;
@ -337,41 +270,31 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
mylog(log_info, "(re)sent handshake2\n");
return 0;
}
else
{
} else {
return 0;
}
return 0;
}
else if(conn_info.state.client_current_state==client_ready)
{
} else if (conn_info.state.client_current_state == client_ready) {
fail_time_counter = 0;
mylog(log_trace, "time %llu,%llu\n", get_current_time(), conn_info.last_state_time);
if(get_current_time()-conn_info.last_hb_recv_time>client_conn_timeout)
{
if (get_current_time() - conn_info.last_hb_recv_time > client_conn_timeout) {
conn_info.state.client_current_state = client_idle;
conn_info.my_id = get_true_random_number_nz();
mylog(log_info, "state back to client_idle from client_ready bc of server-->client direction timeout\n");
return 0;
}
if(get_current_time()- conn_info.last_oppsite_roller_time>client_conn_uplink_timeout)
{
if (get_current_time() - conn_info.last_oppsite_roller_time > client_conn_uplink_timeout) {
conn_info.state.client_current_state = client_idle;
conn_info.my_id = get_true_random_number_nz();
mylog(log_info, "state back to client_idle from client_ready bc of client-->server direction timeout\n");
}
if(get_current_time()-conn_info.last_hb_sent_time<heartbeat_interval)
{
if (get_current_time() - conn_info.last_hb_sent_time < heartbeat_interval) {
return 0;
}
mylog(log_debug, "heartbeat sent <%x,%x>\n", conn_info.oppsite_id, conn_info.my_id);
if (hb_mode == 0)
@ -380,27 +303,22 @@ int client_on_timer(conn_info_t &conn_info) //for client. called when a timer is
send_safer(conn_info, 'h', hb_buf, hb_len);
conn_info.last_hb_sent_time = get_current_time();
return 0;
}
else
{
} else {
mylog(log_fatal, "unknown state,this shouldnt happen.\n");
myexit(-1);
}
return 0;
}
int client_on_raw_recv_hs2_or_ready(conn_info_t &conn_info,char type,char *data,int data_len)
{
int client_on_raw_recv_hs2_or_ready(conn_info_t &conn_info, char type, char *data, int data_len) {
packet_info_t &send_info = conn_info.raw_info.send_info;
packet_info_t &recv_info = conn_info.raw_info.recv_info;
if(!recv_info.new_src_ip.equal(send_info.new_dst_ip)||recv_info.src_port!=send_info.dst_port)
{
if (!recv_info.new_src_ip.equal(send_info.new_dst_ip) || recv_info.src_port != send_info.dst_port) {
mylog(log_warn, "unexpected adress %s %s %d %d,this shouldnt happen.\n", recv_info.new_src_ip.get_str1(), send_info.new_dst_ip.get_str2(), recv_info.src_port, send_info.dst_port);
return -1;
}
if(conn_info.state.client_current_state==client_handshake2)
{
if (conn_info.state.client_current_state == client_handshake2) {
mylog(log_info, "changed state from to client_handshake2 to client_ready\n");
conn_info.state.client_current_state = client_ready;
conn_info.last_hb_sent_time = 0;
@ -408,14 +326,11 @@ int client_on_raw_recv_hs2_or_ready(conn_info_t &conn_info,char type,char *data,
conn_info.last_oppsite_roller_time = conn_info.last_hb_recv_time;
client_on_timer(conn_info);
}
if(data_len>=0&&type=='h')
{
if (data_len >= 0 && type == 'h') {
mylog(log_debug, "[hb]heart beat received,oppsite_roller=%d\n", int(conn_info.oppsite_roller));
conn_info.last_hb_recv_time = get_current_time();
return 0;
}
else if(data_len>= int( sizeof(u32_t))&&type=='d')
{
} else if (data_len >= int(sizeof(u32_t)) && type == 'd') {
mylog(log_trace, "received a data from fake tcp,len:%d\n", data_len);
if (hb_mode == 0)
@ -425,8 +340,7 @@ int client_on_raw_recv_hs2_or_ready(conn_info_t &conn_info,char type,char *data,
memcpy(&tmp_conv_id, &data[0], sizeof(tmp_conv_id));
tmp_conv_id = ntohl(tmp_conv_id);
if(!conn_info.blob->conv_manager.c.is_conv_used(tmp_conv_id))
{
if (!conn_info.blob->conv_manager.c.is_conv_used(tmp_conv_id)) {
mylog(log_info, "unknow conv %d,ignore\n", tmp_conv_id);
return 0;
}
@ -443,17 +357,13 @@ int client_on_raw_recv_hs2_or_ready(conn_info_t &conn_info,char type,char *data,
// tmp_sockaddr.sin_port= htons(uint16_t((u64<<32u)>>32u));
int ret = sendto(udp_fd, data + sizeof(u32_t), data_len - (sizeof(u32_t)), 0, (struct sockaddr *)&tmp_addr.inner, tmp_addr.get_len());
if(ret<0)
{
if (ret < 0) {
mylog(log_warn, "sento returned %d,%s,%02x,%s\n", ret, get_sock_error(), int(tmp_addr.get_type()), tmp_addr.get_str());
// perror("ret<0");
}
}
else
{
} else {
mylog(log_warn, "unknown packet,this shouldnt happen.\n");
return -1;
}
@ -461,7 +371,8 @@ int client_on_raw_recv_hs2_or_ready(conn_info_t &conn_info,char type,char *data,
}
int client_on_raw_recv(conn_info_t &conn_info) // called when raw fd received a packet.
{
char* data;int data_len;
char *data;
int data_len;
packet_info_t &send_info = conn_info.raw_info.send_info;
packet_info_t &recv_info = conn_info.raw_info.recv_info;
@ -473,36 +384,31 @@ int client_on_raw_recv(conn_info_t &conn_info) //called when raw fd received a p
if (pre_recv_raw_packet() < 0) return -1;
#endif
if(conn_info.state.client_current_state==client_idle )
{
if (conn_info.state.client_current_state == client_idle) {
discard_raw_packet();
// recv(raw_recv_fd, 0,0, 0 );
}
else if(conn_info.state.client_current_state==client_tcp_handshake||conn_info.state.client_current_state==client_tcp_handshake_dummy)//received syn ack
} else if (conn_info.state.client_current_state == client_tcp_handshake || conn_info.state.client_current_state == client_tcp_handshake_dummy) // received syn ack
{
assert(raw_mode == mode_faketcp);
if(recv_raw0(raw_info,data,data_len)<0)
{
if (recv_raw0(raw_info, data, data_len) < 0) {
return -1;
}
if(!recv_info.new_src_ip.equal(send_info.new_dst_ip)||recv_info.src_port!=send_info.dst_port)
{
if (data_len >= max_data_len + 1) {
mylog(log_debug, "data_len=%d >= max_data_len+1,ignored", data_len);
return -1;
}
if (!recv_info.new_src_ip.equal(send_info.new_dst_ip) || recv_info.src_port != send_info.dst_port) {
mylog(log_debug, "unexpected adress %s %s %d %d\n", recv_info.new_src_ip.get_str1(), send_info.new_dst_ip.get_str2(), recv_info.src_port, send_info.dst_port);
return -1;
}
if(data_len==0&&raw_info.recv_info.syn==1&&raw_info.recv_info.ack==1)
{
if(conn_info.state.client_current_state==client_tcp_handshake)
{
if(recv_info.ack_seq!=send_info.seq+1)
{
if (data_len == 0 && raw_info.recv_info.syn == 1 && raw_info.recv_info.ack == 1) {
if (conn_info.state.client_current_state == client_tcp_handshake) {
if (recv_info.ack_seq != send_info.seq + 1) {
mylog(log_debug, "seq ack_seq mis match\n");
return -1;
}
mylog(log_info, "state changed from client_tcp_handshake to client_handshake1\n");
}
else
{
} else {
send_info.seq = recv_info.ack_seq - 1;
mylog(log_info, "state changed from client_tcp_dummy to client_handshake1\n");
// send_info.ack_seq=recv_info.seq+1;
@ -513,27 +419,21 @@ int client_on_raw_recv(conn_info_t &conn_info) //called when raw fd received a p
conn_info.last_hb_sent_time = 0;
client_on_timer(conn_info);
return 0;
}
else
{
} else {
mylog(log_debug, "unexpected packet type,expected:syn ack\n");
return -1;
}
}
else if(conn_info.state.client_current_state==client_handshake1)//recevied respond of handshake1
{
if(recv_bare(raw_info,data,data_len)!=0)
} else if (conn_info.state.client_current_state == client_handshake1) // recevied respond of handshake1
{
if (recv_bare(raw_info, data, data_len) != 0) {
mylog(log_debug, "recv_bare failed!\n");
return -1;
}
if(!recv_info.new_src_ip.equal(send_info.new_dst_ip)||recv_info.src_port!=send_info.dst_port)
{
if (!recv_info.new_src_ip.equal(send_info.new_dst_ip) || recv_info.src_port != send_info.dst_port) {
mylog(log_debug, "unexpected adress %s %s %d %d\n", recv_info.new_src_ip.get_str1(), send_info.new_dst_ip.get_str2(), recv_info.src_port, send_info.dst_port);
return -1;
}
if(data_len<int( 3*sizeof(my_id_t)))
{
if (data_len < int(3 * sizeof(my_id_t))) {
mylog(log_debug, "too short to be a handshake\n");
return -1;
}
@ -549,22 +449,17 @@ int client_on_raw_recv(conn_info_t &conn_info) //called when raw fd received a p
memcpy(&tmp_oppsite_const_id, &data[sizeof(my_id_t) * 2], sizeof(tmp_oppsite_const_id));
tmp_oppsite_const_id = ntohl(tmp_oppsite_const_id);
if(tmp_my_id!=conn_info.my_id)
{
if (tmp_my_id != conn_info.my_id) {
mylog(log_debug, "tmp_my_id doesnt match\n");
return -1;
}
if(raw_mode==mode_faketcp)
{
if(recv_info.ack_seq!=send_info.seq)
{
if (raw_mode == mode_faketcp) {
if (recv_info.ack_seq != send_info.seq) {
mylog(log_debug, "seq ack_seq mis match\n");
return -1;
}
if(recv_info.seq!=send_info.ack_seq)
{
if (recv_info.seq != send_info.ack_seq) {
mylog(log_debug, "seq ack_seq mis match\n");
return -1;
}
@ -579,20 +474,17 @@ int client_on_raw_recv(conn_info_t &conn_info) //called when raw fd received a p
client_on_timer(conn_info);
return 0;
}
else if(conn_info.state.client_current_state==client_handshake2||conn_info.state.client_current_state==client_ready)//received heartbeat or data
} else if (conn_info.state.client_current_state == client_handshake2 || conn_info.state.client_current_state == client_ready) // received heartbeat or data
{
vector<char> type_vec;
vector<string> data_vec;
recv_safer_multi(conn_info, type_vec, data_vec);
if(data_vec.empty())
{
if (data_vec.empty()) {
mylog(log_debug, "recv_safer failed!\n");
return -1;
}
for(int i=0;i<(int)type_vec.size();i++)
{
for (int i = 0; i < (int)type_vec.size(); i++) {
char type = type_vec[i];
char *data = (char *)data_vec[i].c_str(); // be careful, do not append data to it
int data_len = data_vec[i].length();
@ -600,16 +492,13 @@ int client_on_raw_recv(conn_info_t &conn_info) //called when raw fd received a p
}
return 0;
}
else
{
} else {
mylog(log_fatal, "unknown state,this shouldnt happen.\n");
myexit(-1);
}
return 0;
}
int client_on_udp_recv(conn_info_t &conn_info)
{
int client_on_udp_recv(conn_info_t &conn_info) {
int recv_len;
char buf[buf_len];
address_t::storage_t udp_new_addr_in = {{0}};
@ -621,14 +510,12 @@ int client_on_udp_recv(conn_info_t &conn_info)
// myexit(1);
};
if(recv_len==max_data_len+1)
{
if (recv_len == max_data_len + 1) {
mylog(log_warn, "huge packet, data_len > %d,dropped\n", max_data_len);
return -1;
}
if(recv_len>=mtu_warn)
{
if (recv_len >= mtu_warn) {
mylog(log_warn, "huge packet,data len=%d (>=%d).strongly suggested to set a smaller mtu at upper level,to get rid of this warn\n ", recv_len, mtu_warn);
}
@ -636,53 +523,45 @@ int client_on_udp_recv(conn_info_t &conn_info)
tmp_addr.from_sockaddr((sockaddr *)&udp_new_addr_in, udp_new_addr_len);
u32_t conv;
if(!conn_info.blob->conv_manager.c.is_data_used(tmp_addr))
{
if(conn_info.blob->conv_manager.c.get_size() >=max_conv_num)
{
if (!conn_info.blob->conv_manager.c.is_data_used(tmp_addr)) {
if (conn_info.blob->conv_manager.c.get_size() >= max_conv_num) {
mylog(log_warn, "ignored new udp connect bc max_conv_num exceed\n");
return -1;
}
conv = conn_info.blob->conv_manager.c.get_new_conv();
conn_info.blob->conv_manager.c.insert_conv(conv, tmp_addr);
mylog(log_info, "new packet from %s,conv_id=%x\n", tmp_addr.get_str(), conv);
}
else
{
} else {
conv = conn_info.blob->conv_manager.c.find_conv_by_data(tmp_addr);
}
conn_info.blob->conv_manager.c.update_active_time(conv);
if(conn_info.state.client_current_state==client_ready)
{
if (conn_info.state.client_current_state == client_ready) {
send_data_safer(conn_info, buf, recv_len, conv);
}
return 0;
}
void udp_accept_cb(struct ev_loop *loop, struct ev_io *watcher, int revents)
{
void udp_accept_cb(struct ev_loop *loop, struct ev_io *watcher, int revents) {
conn_info_t &conn_info = *((conn_info_t *)watcher->data);
client_on_udp_recv(conn_info);
}
void raw_recv_cb(struct ev_loop *loop, struct ev_io *watcher, int revents)
{
void raw_recv_cb(struct ev_loop *loop, struct ev_io *watcher, int revents) {
if (is_udp2raw_mp) assert(0 == 1);
conn_info_t &conn_info = *((conn_info_t *)watcher->data);
client_on_raw_recv(conn_info);
}
#ifdef UDP2RAW_MP
void async_cb(struct ev_loop *loop, struct ev_async *watcher, int revents)
{
void async_cb(struct ev_loop *loop, struct ev_async *watcher, int revents) {
conn_info_t &conn_info = *((conn_info_t *)watcher->data);
if(send_with_pcap&&!pcap_header_captured)
{
int empty=0;char *p;int len;
if (send_with_pcap && !pcap_header_captured) {
int empty = 0;
char *p;
int len;
pthread_mutex_lock(&queue_mutex);
empty = my_queue.empty();
if(!empty)
{
if (!empty) {
my_queue.peek_front(p, len);
my_queue.pop_front();
}
@ -704,22 +583,21 @@ void async_cb(struct ev_loop *loop, struct ev_async *watcher, int revents)
}
// mylog(log_info,"async_cb called\n");
while(1)
{
int empty=0;char *p;int len;
while (1) {
int empty = 0;
char *p;
int len;
pthread_mutex_lock(&queue_mutex);
empty = my_queue.empty();
if(!empty)
{
if (!empty) {
my_queue.peek_front(p, len);
my_queue.pop_front();
}
pthread_mutex_unlock(&queue_mutex);
if (empty) break;
if(g_fix_gro==0&&len>max_data_len)
{
mylog(log_warn,"huge packet %d > %d, dropped\n",len,max_data_len);
if (g_fix_gro == 0 && len > max_data_len) {
mylog(log_warn, "huge packet %d > %d, dropped. maybe you need to turn down mtu at upper level, or maybe you need the --fix-gro option\n", len, max_data_len);
break;
}
@ -732,21 +610,18 @@ void async_cb(struct ev_loop *loop, struct ev_async *watcher, int revents)
}
}
#endif
void clear_timer_cb(struct ev_loop *loop, struct ev_timer *watcher, int revents)
{
void clear_timer_cb(struct ev_loop *loop, struct ev_timer *watcher, int revents) {
conn_info_t &conn_info = *((conn_info_t *)watcher->data);
client_on_timer(conn_info);
}
void fifo_cb(struct ev_loop *loop, struct ev_io *watcher, int revents)
{
void fifo_cb(struct ev_loop *loop, struct ev_io *watcher, int revents) {
conn_info_t &conn_info = *((conn_info_t *)watcher->data);
char buf[buf_len];
int fifo_fd = watcher->fd;
int len = read(fifo_fd, buf, sizeof(buf));
if(len<0)
{
if (len < 0) {
mylog(log_warn, "fifo read failed len=%d,errno=%s\n", len, get_sock_error());
return;
}
@ -754,20 +629,15 @@ void fifo_cb(struct ev_loop *loop, struct ev_io *watcher, int revents)
while (len >= 1 && buf[len - 1] == '\n')
buf[len - 1] = 0;
mylog(log_info, "got data from fifo,len=%d,s=[%s]\n", len, buf);
if(strcmp(buf,"reconnect")==0)
{
if (strcmp(buf, "reconnect") == 0) {
mylog(log_info, "received command: reconnect\n");
conn_info.state.client_current_state = client_idle;
conn_info.my_id = get_true_random_number_nz();
}
else
{
} else {
mylog(log_info, "unknown command\n");
}
}
int client_event_loop()
{
int client_event_loop() {
char buf[buf_len];
conn_info_t conn_info;
@ -778,10 +648,8 @@ int client_event_loop()
packet_info_t &recv_info = conn_info.raw_info.recv_info;
#ifdef UDP2RAW_LINUX
if(lower_level)
{
if(lower_level_manual)
{
if (lower_level) {
if (lower_level_manual) {
int index;
init_ifindex(if_name, raw_send_fd, index);
// init_ifindex(if_name);
@ -792,37 +660,26 @@ int client_event_loop()
send_info.addr_ll.sll_protocol = htons(ETH_P_IP);
memcpy(&send_info.addr_ll.sll_addr, dest_hw_addr, ETHER_ADDR_LEN);
mylog(log_info, "we are running at lower-level (manual) mode\n");
}
else
{
} else {
u32_t dest_ip;
string if_name_string;
string hw_string;
assert(remote_addr.get_type() == AF_INET);
if(retry_on_error==0)
{
if(find_lower_level_info(remote_addr.inner.ipv4.sin_addr.s_addr,dest_ip,if_name_string,hw_string)!=0)
{
if (retry_on_error == 0) {
if (find_lower_level_info(remote_addr.inner.ipv4.sin_addr.s_addr, dest_ip, if_name_string, hw_string) != 0) {
mylog(log_fatal, "auto detect lower-level info failed for %s,specific it manually\n", remote_addr.get_ip());
myexit(-1);
}
}
else
{
} else {
int ok = 0;
while(!ok)
{
if(find_lower_level_info(remote_addr.inner.ipv4.sin_addr.s_addr,dest_ip,if_name_string,hw_string)!=0)
{
while (!ok) {
if (find_lower_level_info(remote_addr.inner.ipv4.sin_addr.s_addr, dest_ip, if_name_string, hw_string) != 0) {
mylog(log_warn, "auto detect lower-level info failed for %s,retry in %d seconds\n", remote_addr.get_ip(), retry_on_error_interval);
sleep(retry_on_error_interval);
}
else
{
} else {
ok = 1;
}
}
}
mylog(log_info, "we are running at lower-level (auto) mode,%s %s %s\n", my_ntoa(dest_ip), if_name_string.c_str(), hw_string.c_str());
@ -851,20 +708,17 @@ int client_event_loop()
memcpy(&send_info.addr_ll.sll_addr, dest_hw_addr, ETHER_ADDR_LEN);
// mylog(log_info,"we are running at lower-level (manual) mode\n");
}
}
#endif
#ifdef UDP2RAW_MP
address_t tmp_addr;
if(get_src_adress2(tmp_addr,remote_addr)!=0)
{
if (get_src_adress2(tmp_addr, remote_addr) != 0) {
mylog(log_error, "get_src_adress() failed\n");
myexit(-1);
}
if(strcmp(dev,"")==0)
{
if (strcmp(dev, "") == 0) {
mylog(log_info, "--dev have not been set, trying to detect automatically, available devices:\n");
mylog(log_info, "available device(device name: ip address ; description):\n");
@ -874,8 +728,7 @@ int client_event_loop()
int found = 0;
pcap_if_t *interfaces, *d;
if(pcap_findalldevs(&interfaces,errbuf)==-1)
{
if (pcap_findalldevs(&interfaces, errbuf) == -1) {
mylog(log_fatal, "error in pcap_findalldevs(),%s\n", errbuf);
myexit(-1);
}
@ -884,82 +737,61 @@ int client_event_loop()
log_bare(log_warn, "%s:", d->name);
int cnt = 0;
for (pcap_addr_t *a = d->addresses; a != NULL; a = a->next) {
if(a->addr==NULL)
{
if (a->addr == NULL) {
log_bare(log_debug, " [a->addr==NULL]");
continue;
}
if(a->addr->sa_family == AF_INET||a->addr->sa_family == AF_INET6)
{
if (a->addr->sa_family == AF_INET || a->addr->sa_family == AF_INET6) {
cnt++;
if(a->addr->sa_family ==AF_INET)
{
if (a->addr->sa_family == AF_INET) {
char s[max_addr_len];
inet_ntop(AF_INET, &((struct sockaddr_in *)a->addr)->sin_addr, s, max_addr_len);
log_bare(log_warn, " [%s]", s);
if(a->addr->sa_family==raw_ip_version)
{
if(((struct sockaddr_in*)a->addr)->sin_addr.s_addr ==tmp_addr.inner.ipv4.sin_addr.s_addr)
{
if (a->addr->sa_family == raw_ip_version) {
if (((struct sockaddr_in *)a->addr)->sin_addr.s_addr == tmp_addr.inner.ipv4.sin_addr.s_addr) {
found++;
strcpy(dev, d->name);
}
}
}
else
{
} else {
assert(a->addr->sa_family == AF_INET6);
char s[max_addr_len];
inet_ntop(AF_INET6, &((struct sockaddr_in6 *)a->addr)->sin6_addr, s, max_addr_len);
log_bare(log_warn, " [%s]", s);
if(a->addr->sa_family==raw_ip_version)
{
if( memcmp( &((struct sockaddr_in6*)a->addr)->sin6_addr,&tmp_addr.inner.ipv6.sin6_addr,sizeof(struct in6_addr))==0 )
{
if (a->addr->sa_family == raw_ip_version) {
if (memcmp(&((struct sockaddr_in6 *)a->addr)->sin6_addr, &tmp_addr.inner.ipv6.sin6_addr, sizeof(struct in6_addr)) == 0) {
found++;
strcpy(dev, d->name);
}
}
}
}
else
{
} else {
log_bare(log_debug, " [unknow:%d]", int(a->addr->sa_family));
}
}
if (cnt == 0) log_bare(log_warn, " [no ip found]");
if(d->description==0)
{
if (d->description == 0) {
log_bare(log_warn, "; (no description available)");
}
else
{
} else {
log_bare(log_warn, "; %s", d->description);
}
log_bare(log_warn, "\n");
}
if(found==0)
{
if (found == 0) {
mylog(log_fatal, "no matched device found for ip: [%s]\n", tmp_addr.get_ip());
myexit(-1);
}
else if(found==1)
{
} else if (found == 1) {
mylog(log_info, "using device:[%s], ip: [%s]\n", dev, tmp_addr.get_ip());
}
else
{
} else {
mylog(log_fatal, "more than one devices found for ip: [%s] , you need to use --dev manually\n", tmp_addr.get_ip());
myexit(-1);
}
}
else
{
} else {
mylog(log_info, "--dev has been manually set, using device:[%s]\n", dev);
}
#endif
@ -967,17 +799,15 @@ int client_event_loop()
send_info.src_port = 0;
memset(&send_info.new_src_ip, 0, sizeof(send_info.new_src_ip));
int i, j, k;int ret;
int i, j, k;
int ret;
send_info.new_dst_ip.from_address_t(remote_addr);
send_info.dst_port = remote_addr.get_port();
udp_fd = socket(local_addr.get_type(), SOCK_DGRAM, IPPROTO_UDP);
set_buf_size(udp_fd, socket_buf_size);
if (::bind(udp_fd, (struct sockaddr *)&local_addr.inner, local_addr.get_len()) == -1) {
mylog(log_fatal, "socket bind error\n");
// perror("socket bind error");
@ -1005,14 +835,12 @@ int client_event_loop()
// myexit(-1);
// }
struct ev_io udp_accept_watcher;
udp_accept_watcher.data = &conn_info;
ev_io_init(&udp_accept_watcher, udp_accept_cb, udp_fd, EV_READ);
ev_io_start(loop, &udp_accept_watcher);
// ev.events = EPOLLIN;
// ev.data.u64 = raw_recv_fd;
@ -1053,8 +881,7 @@ int client_event_loop()
struct ev_io fifo_watcher;
fifo_watcher.data = &conn_info;
if(fifo_file[0]!=0)
{
if (fifo_file[0] != 0) {
fifo_fd = create_fifo(fifo_file);
ev_io_init(&fifo_watcher, fifo_cb, fifo_fd, EV_READ);

502
common.cpp
View File

File diff suppressed because it is too large Load Diff

174
common.h
View File

@ -44,7 +44,6 @@ const int is_udp2raw_mp=1;
#include <libnet.h>
#endif
#else
#define UDP2RAW_LINUX
const int is_udp2raw_mp = 0;
@ -80,7 +79,6 @@ typedef int socklen_t;
#include <netinet/in.h>
#endif
#include <unordered_map>
#include <fstream>
#include <string>
@ -100,7 +98,6 @@ using namespace std;
#define UDP2RAW_BIG_ENDIAN 1
#endif
#if defined(__BYTE_ORDER) && __BYTE_ORDER == __LITTLE_ENDIAN || \
defined(__BYTE_ORDER__) && __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__ || \
defined(__LITTLE_ENDIAN__) || \
@ -115,12 +112,10 @@ using namespace std;
#error "endian detection conflicts"
#endif
#if !defined(UDP2RAW_BIG_ENDIAN) && !defined(UDP2RAW_LITTLE_ENDIAN)
#error "endian detection failed"
#endif
#if defined(__MINGW32__)
int inet_pton(int af, const char *src, void *dst);
const char *inet_ntop(int af, const void *src, char *dst, socklen_t size);
@ -132,20 +127,17 @@ int get_sock_errno();
#if defined(__MINGW32__)
typedef SOCKET my_fd_t;
inline int sock_close(my_fd_t fd)
{
inline int sock_close(my_fd_t fd) {
return closesocket(fd);
}
#else
typedef int my_fd_t;
inline int sock_close(my_fd_t fd)
{
inline int sock_close(my_fd_t fd) {
return close(fd);
}
#endif
typedef unsigned long long u64_t; // this works on most platform,avoid using the PRId64
typedef long long i64_t;
@ -188,10 +180,8 @@ u32_t sdbm(unsigned char *str,int len);
struct address_t // TODO scope id
{
struct hash_function
{
u32_t operator()(const address_t &key) const
{
struct hash_function {
u32_t operator()(const address_t &key) const {
return sdbm((unsigned char *)&key.inner, sizeof(key.inner));
}
};
@ -203,16 +193,13 @@ struct address_t //TODO scope id
};
storage_t inner;
address_t()
{
address_t() {
clear();
}
void clear()
{
void clear() {
memset(&inner, 0, sizeof(inner));
}
int from_ip_port(u32_t ip, int port)
{
int from_ip_port(u32_t ip, int port) {
clear();
inner.ipv4.sin_family = AF_INET;
inner.ipv4.sin_port = htons(port);
@ -220,17 +207,13 @@ struct address_t //TODO scope id
return 0;
}
int from_ip_port_new(int type, void * ip, int port)
{
int from_ip_port_new(int type, void *ip, int port) {
clear();
if(type==AF_INET)
{
if (type == AF_INET) {
inner.ipv4.sin_family = AF_INET;
inner.ipv4.sin_port = htons(port);
inner.ipv4.sin_addr.s_addr = *((u32_t *)ip);
}
else if(type==AF_INET6)
{
} else if (type == AF_INET6) {
inner.ipv6.sin6_family = AF_INET6;
inner.ipv6.sin6_port = htons(port);
inner.ipv6.sin6_addr = *((in6_addr *)ip);
@ -247,18 +230,15 @@ struct address_t //TODO scope id
char *get_str();
void to_str(char *);
inline u32_t get_type()
{
inline u32_t get_type() {
u32_t ret = ((sockaddr *)&inner)->sa_family;
assert(ret == AF_INET || ret == AF_INET6);
return ret;
}
inline u32_t get_len()
{
inline u32_t get_len() {
u32_t type = get_type();
switch(type)
{
switch (type) {
case AF_INET:
return sizeof(sockaddr_in);
case AF_INET6:
@ -269,11 +249,9 @@ struct address_t //TODO scope id
return -1;
}
inline u32_t get_port()
{
inline u32_t get_port() {
u32_t type = get_type();
switch(type)
{
switch (type) {
case AF_INET:
return ntohs(inner.ipv4.sin_port);
case AF_INET6:
@ -284,11 +262,9 @@ struct address_t //TODO scope id
return -1;
}
inline void set_port(int port)
{
inline void set_port(int port) {
u32_t type = get_type();
switch(type)
{
switch (type) {
case AF_INET:
inner.ipv4.sin_port = htons(port);
break;
@ -301,8 +277,7 @@ struct address_t //TODO scope id
return;
}
bool operator == (const address_t &b) const
{
bool operator==(const address_t &b) const {
// return this->data==b.data;
return memcmp(&this->inner, &b.inner, sizeof(this->inner)) == 0;
}
@ -314,16 +289,13 @@ struct address_t //TODO scope id
namespace std {
template <>
struct hash<address_t>
{
std::size_t operator()(const address_t& key) const
{
struct hash<address_t> {
std::size_t operator()(const address_t &key) const {
// return address_t::hash_function(k);
return sdbm((unsigned char *)&key.inner, sizeof(key.inner));
}
};
}
} // namespace std
union my_ip_t // just a simple version of address_t,stores ip only
{
@ -337,21 +309,15 @@ union my_ip_t //just a simple version of address_t,stores ip only
char *get_str2() const;
int from_address_t(address_t a);
};
struct not_copy_able_t
{
not_copy_able_t()
{
struct not_copy_able_t {
not_copy_able_t() {
}
not_copy_able_t(const not_copy_able_t &other)
{
not_copy_able_t(const not_copy_able_t &other) {
assert(0 == 1);
}
const not_copy_able_t & operator=(const not_copy_able_t &other)
{
const not_copy_able_t &operator=(const not_copy_able_t &other) {
assert(0 == 1);
return other;
}
@ -368,44 +334,43 @@ const int buf_len=max_data_len+400;
#ifdef UDP2RAW_MP
const int queue_len = 200;
struct queue_t
{
struct queue_t {
char data[queue_len][huge_buf_len];
int data_len[queue_len];
int head = 0;
int tail = 0;
void clear()
{
void clear() {
head = tail = 0;
}
int empty()
{
if(head==tail) return 1;
else return 0;
int empty() {
if (head == tail)
return 1;
else
return 0;
}
int full()
{
if( (tail+1)%queue_len==head ) return 1;
else return 0;
int full() {
if ((tail + 1) % queue_len == head)
return 1;
else
return 0;
}
void peek_front(char * & p,int &len)
{
void peek_front(char *&p, int &len) {
assert(!empty());
p = data[head];
len = data_len[head];
}
void pop_front()
{
void pop_front() {
assert(!empty());
head++;head%=queue_len;
head++;
head %= queue_len;
}
void push_back(char * p,int len)
{
void push_back(char *p, int len) {
assert(!full());
memcpy(data[tail], p, len);
data_len[tail] = len;
tail++;tail%=queue_len;
tail++;
tail %= queue_len;
}
};
@ -474,12 +439,10 @@ int create_fifo(char * file);
void print_binary_chars(const char *a, int len);
template <class key_t>
struct lru_collector_t:not_copy_able_t
{
struct lru_collector_t : not_copy_able_t {
// typedef void* key_t;
//#define key_t void*
struct lru_pair_t
{
struct lru_pair_t {
key_t key;
my_time_t ts;
};
@ -487,65 +450,61 @@ struct lru_collector_t:not_copy_able_t
unordered_map<key_t, typename list<lru_pair_t>::iterator> mp;
list<lru_pair_t> q;
int update(key_t key)
{
int update(key_t key) {
assert(mp.find(key) != mp.end());
auto it = mp[key];
q.erase(it);
my_time_t value = get_current_time();
if(!q.empty())
{
if (!q.empty()) {
assert(value >= q.front().ts);
}
lru_pair_t tmp; tmp.key=key; tmp.ts=value;
lru_pair_t tmp;
tmp.key = key;
tmp.ts = value;
q.push_front(tmp);
mp[key] = q.begin();
return 0;
}
int new_key(key_t key)
{
int new_key(key_t key) {
assert(mp.find(key) == mp.end());
my_time_t value = get_current_time();
if(!q.empty())
{
if (!q.empty()) {
assert(value >= q.front().ts);
}
lru_pair_t tmp; tmp.key=key; tmp.ts=value;
lru_pair_t tmp;
tmp.key = key;
tmp.ts = value;
q.push_front(tmp);
mp[key] = q.begin();
return 0;
}
int size()
{
int size() {
return q.size();
}
int empty()
{
int empty() {
return q.empty();
}
void clear()
{
mp.clear(); q.clear();
void clear() {
mp.clear();
q.clear();
}
my_time_t ts_of(key_t key)
{
my_time_t ts_of(key_t key) {
assert(mp.find(key) != mp.end());
return mp[key]->ts;
}
my_time_t peek_back(key_t &key)
{
my_time_t peek_back(key_t &key) {
assert(!q.empty());
auto it=q.end(); it--;
auto it = q.end();
it--;
key = it->key;
return it->ts;
}
void erase(key_t key)
{
void erase(key_t key) {
assert(mp.find(key) != mp.end());
q.erase(mp[key]);
mp.erase(key);
@ -560,5 +519,4 @@ struct lru_collector_t:not_copy_able_t
}*/
};
#endif /* COMMON_H_ */

289
connection.cpp
View File

@ -15,67 +15,53 @@ const int disable_conn_clear=0;//a raw connection is called conn.
conn_manager_t conn_manager;
anti_replay_seq_t anti_replay_t::get_new_seq_for_send()
{
anti_replay_seq_t anti_replay_t::get_new_seq_for_send() {
return anti_replay_seq++;
}
anti_replay_t::anti_replay_t()
{
anti_replay_t::anti_replay_t() {
max_packet_received = 0;
anti_replay_seq = get_true_random_number_64() / 10; // random first seq
// memset(window,0,sizeof(window)); //not necessary
}
void anti_replay_t::re_init()
{
void anti_replay_t::re_init() {
max_packet_received = 0;
// memset(window,0,sizeof(window));
}
int anti_replay_t::is_vaild(u64_t seq)
{
int anti_replay_t::is_vaild(u64_t seq) {
if (disable_anti_replay) return 1;
// if(disabled) return 0;
if(seq==max_packet_received) return 0;
else if(seq>max_packet_received)
{
if(seq-max_packet_received>=anti_replay_window_size)
{
if (seq == max_packet_received)
return 0;
else if (seq > max_packet_received) {
if (seq - max_packet_received >= anti_replay_window_size) {
memset(window, 0, sizeof(window));
window[seq % anti_replay_window_size] = 1;
}
else
{
} else {
for (u64_t i = max_packet_received + 1; i < seq; i++)
window[i % anti_replay_window_size] = 0;
window[seq % anti_replay_window_size] = 1;
}
max_packet_received = seq;
return 1;
}
else if(seq<max_packet_received)
{
if(max_packet_received-seq>=anti_replay_window_size) return 0;
else
{
if (window[seq%anti_replay_window_size]==1) return 0;
else
{
} else if (seq < max_packet_received) {
if (max_packet_received - seq >= anti_replay_window_size)
return 0;
else {
if (window[seq % anti_replay_window_size] == 1)
return 0;
else {
window[seq % anti_replay_window_size] = 1;
return 1;
}
}
}
return 0; // for complier check
}
void conn_info_t::recover(const conn_info_t &conn_info)
{
void conn_info_t::recover(const conn_info_t &conn_info) {
raw_info = conn_info.raw_info;
raw_info.rst_received = 0;
@ -91,11 +77,9 @@ conn_manager_t conn_manager;
my_roller = 0; // no need to set,but for easier debug,set it to zero
oppsite_roller = 0; // same as above
last_oppsite_roller_time = 0;
}
void conn_info_t::re_init()
{
void conn_info_t::re_init() {
// send_packet_info.protocol=g_packet_info_send.protocol;
if (program_mode == server_mode)
state.server_current_state = server_idle;
@ -110,49 +94,37 @@ conn_manager_t conn_manager;
oppsite_roller = 0;
last_oppsite_roller_time = 0;
}
conn_info_t::conn_info_t()
{
conn_info_t::conn_info_t() {
blob = 0;
re_init();
}
void conn_info_t::prepare()
{
void conn_info_t::prepare() {
assert(blob == 0);
blob = new blob_t;
if(program_mode==server_mode)
{
if (program_mode == server_mode) {
blob->conv_manager.s.additional_clear_function = server_clear_function;
}
else
{
} else {
assert(program_mode == client_mode);
}
}
conn_info_t::conn_info_t(const conn_info_t&b)
{
conn_info_t::conn_info_t(const conn_info_t &b) {
assert(0 == 1);
// mylog(log_error,"called!!!!!!!!!!!!!\n");
}
conn_info_t& conn_info_t::operator=(const conn_info_t& b)
{
conn_info_t &conn_info_t::operator=(const conn_info_t &b) {
mylog(log_fatal, "not allowed\n");
myexit(-1);
return *this;
}
conn_info_t::~conn_info_t()
{
if(program_mode==server_mode)
{
if(state.server_current_state==server_ready)
{
conn_info_t::~conn_info_t() {
if (program_mode == server_mode) {
if (state.server_current_state == server_ready) {
assert(blob != 0);
assert(oppsite_const_id != 0);
// assert(conn_manager.const_id_mp.find(oppsite_const_id)!=conn_manager.const_id_mp.end()); // conn_manager 's deconstuction function erases it
}
else
{
} else {
assert(blob == 0);
assert(oppsite_const_id == 0);
}
@ -166,9 +138,7 @@ conn_manager_t conn_manager;
// send_packet_info.protocol=g_packet_info_send.protocol;
}
conn_manager_t::conn_manager_t()
{
conn_manager_t::conn_manager_t() {
ready_num = 0;
mp.reserve(10007);
// clear_it=mp.begin();
@ -179,14 +149,12 @@ conn_manager_t conn_manager;
// current_ready_ip=0;
// current_ready_port=0;
}
int conn_manager_t::exist(address_t addr)
{
int conn_manager_t::exist(address_t addr) {
// u64_t u64=0;
// u64=ip;
// u64<<=32u;
// u64|=port;
if(mp.find(addr)!=mp.end())
{
if (mp.find(addr) != mp.end()) {
return 1;
}
return 0;
@ -208,13 +176,10 @@ conn_manager_t conn_manager;
// u64<<=32u;
// u64|=port;
unordered_map<address_t, conn_info_t *>::iterator it = mp.find(addr);
if(it==mp.end())
{
if (it == mp.end()) {
mp[addr] = new conn_info_t;
// lru.new_key(addr);
}
else
{
} else {
// lru.update(addr);
}
return mp[addr];
@ -226,21 +191,16 @@ conn_manager_t conn_manager;
// u64<<=32u;
// u64|=port;
unordered_map<address_t, conn_info_t *>::iterator it = mp.find(addr);
if(it==mp.end())
{
if (it == mp.end()) {
mp[addr] = new conn_info_t;
// lru.new_key(addr);
}
else
{
} else {
// lru.update(addr);
}
return *mp[addr];
}
int conn_manager_t::erase(unordered_map<address_t,conn_info_t*>::iterator erase_it)
{
if(erase_it->second->state.server_current_state==server_ready)
{
int conn_manager_t::erase(unordered_map<address_t, conn_info_t *>::iterator erase_it) {
if (erase_it->second->state.server_current_state == server_ready) {
ready_num--;
assert(i32_t(ready_num) != -1);
assert(erase_it->second != 0);
@ -252,7 +212,6 @@ conn_manager_t conn_manager;
assert(erase_it->second->oppsite_const_id != 0);
assert(const_id_mp.find(erase_it->second->oppsite_const_id) != const_id_mp.end());
// assert(timer_fd_mp.find(erase_it->second->timer_fd)!=timer_fd_mp.end());
const_id_mp.erase(erase_it->second->oppsite_const_id);
@ -264,30 +223,24 @@ conn_manager_t conn_manager;
// close(erase_it->second->timer_fd);// close will auto delte it from epoll
delete (erase_it->second);
mp.erase(erase_it->first);
}
else
{
} else {
assert(erase_it->second->blob == 0);
assert(erase_it->second->timer_fd64 == 0);
assert(erase_it->second->oppsite_const_id == 0);
delete (erase_it->second);
mp.erase(erase_it->first);
}
return 0;
}
int conn_manager_t::clear_inactive()
{
if(get_current_time()-last_clear_time>conn_clear_interval)
{
int conn_manager_t::clear_inactive() {
if (get_current_time() - last_clear_time > conn_clear_interval) {
last_clear_time = get_current_time();
return clear_inactive0();
}
return 0;
}
int conn_manager_t::clear_inactive0()
{
int conn_manager_t::clear_inactive0() {
unordered_map<address_t, conn_info_t *>::iterator it;
unordered_map<address_t, conn_info_t *>::iterator old_it;
@ -304,31 +257,22 @@ int conn_manager_t::clear_inactive0()
num_to_clean = min(num_to_clean, (int)mp.size());
u64_t current_time = get_current_time();
for(;;)
{
for (;;) {
if (cnt >= num_to_clean) break;
if (mp.begin() == mp.end()) break;
if(it==mp.end())
{
if (it == mp.end()) {
it = mp.begin();
}
if(it->second->state.server_current_state==server_ready &&current_time - it->second->last_hb_recv_time <=server_conn_timeout)
{
if (it->second->state.server_current_state == server_ready && current_time - it->second->last_hb_recv_time <= server_conn_timeout) {
it++;
}
else if(it->second->state.server_current_state!=server_ready&& current_time - it->second->last_state_time <=server_handshake_timeout )
{
} else if (it->second->state.server_current_state != server_ready && current_time - it->second->last_state_time <= server_handshake_timeout) {
it++;
}
else if(it->second->blob!=0&&it->second->blob->conv_manager.s.get_size() >0)
{
} else if (it->second->blob != 0 && it->second->blob->conv_manager.s.get_size() > 0) {
assert(it->second->state.server_current_state == server_ready);
it++;
}
else
{
} else {
mylog(log_info, "[%s:%d]inactive conn cleared \n", it->second->raw_info.recv_info.new_src_ip.get_str1(), it->second->raw_info.recv_info.src_port);
old_it = it;
it++;
@ -341,13 +285,10 @@ int conn_manager_t::clear_inactive0()
return 0;
}
int send_bare(raw_info_t &raw_info, const char *data, int len) // send function with encryption but no anti replay,this is used when client and server verifys each other
// you have to design the protocol carefully, so that you wont be affect by relay attack
{
if(len<0)
{
if (len < 0) {
mylog(log_debug, "input_len <0\n");
return -1;
}
@ -357,7 +298,6 @@ int send_bare(raw_info_t &raw_info,const char* data,int len)//send function with
char send_data_buf[buf_len]; // buf for send data and send hb
char send_data_buf2[buf_len];
// static send_bare[buf_len];
iv_t iv = get_true_random_number_64();
padding_t padding = get_true_random_number_64();
@ -369,8 +309,7 @@ int send_bare(raw_info_t &raw_info,const char* data,int len)//send function with
memcpy(send_data_buf + sizeof(iv) + sizeof(padding) + 1, data, len);
int new_len = len + sizeof(iv) + sizeof(padding) + 1;
if(my_encrypt(send_data_buf,send_data_buf2,new_len)!=0)
{
if (my_encrypt(send_data_buf, send_data_buf2, new_len) != 0) {
return -1;
}
send_raw0(raw_info, send_data_buf2, new_len);
@ -380,26 +319,22 @@ int reserved_parse_bare(const char *input,int input_len,char* & data,int & len)
{
static char recv_data_buf[buf_len];
if(input_len<0)
{
if (input_len < 0) {
mylog(log_debug, "input_len <0\n");
return -1;
}
if(my_decrypt(input,recv_data_buf,input_len)!=0)
{
if (my_decrypt(input, recv_data_buf, input_len) != 0) {
mylog(log_debug, "decrypt_fail in recv bare\n");
return -1;
}
if(recv_data_buf[sizeof(iv_t)+sizeof(padding_t)]!='b')
{
if (recv_data_buf[sizeof(iv_t) + sizeof(padding_t)] != 'b') {
mylog(log_debug, "not a bare packet\n");
return -1;
}
len = input_len;
data = recv_data_buf + sizeof(iv_t) + sizeof(padding_t) + 1;
len -= sizeof(iv_t) + sizeof(padding_t) + 1;
if(len<0)
{
if (len < 0) {
mylog(log_debug, "len <0\n");
return -1;
}
@ -411,14 +346,18 @@ int recv_bare(raw_info_t &raw_info,char* & data,int & len)//recv function with e
packet_info_t &send_info = raw_info.send_info;
packet_info_t &recv_info = raw_info.recv_info;
if(recv_raw0(raw_info,data,len)<0)
{
if (recv_raw0(raw_info, data, len) < 0) {
// printf("recv_raw_fail in recv bare\n");
return -1;
}
if (len >= max_data_len + 1) {
mylog(log_debug, "data_len=%d >= max_data_len+1,ignored", len);
return -1;
}
mylog(log_trace, "data len=%d\n", len);
if ((raw_mode == mode_faketcp && (recv_info.syn == 1 || recv_info.ack != 1)))
{
if ((raw_mode == mode_faketcp && (recv_info.syn == 1 || recv_info.ack != 1))) {
mylog(log_debug, "unexpect packet type recv_info.syn=%d recv_info.ack=%d \n", recv_info.syn, recv_info.ack);
return -1;
}
@ -430,10 +369,14 @@ int send_handshake(raw_info_t &raw_info,my_id_t id1,my_id_t id2,my_id_t id3)// a
packet_info_t &send_info = raw_info.send_info;
packet_info_t &recv_info = raw_info.recv_info;
char * data;int len;
char *data;
int len;
// len=sizeof(id_t)*3;
if (numbers_to_char(id1, id2, id3, data, len) != 0) return -1;
if(send_bare(raw_info,data,len)!=0) {mylog(log_warn,"send bare fail\n");return -1;}
if (send_bare(raw_info, data, len) != 0) {
mylog(log_warn, "send bare fail\n");
return -1;
}
return 0;
}
/*
@ -449,17 +392,14 @@ int recv_handshake(packet_info_t &info,id_t &id1,id_t &id2,id_t &id3)
int send_safer(conn_info_t &conn_info, char type, const char *data, int len) // safer transfer function with anti-replay,when mutually verification is done.
{
packet_info_t &send_info = conn_info.raw_info.send_info;
packet_info_t &recv_info = conn_info.raw_info.recv_info;
if(type!='h'&&type!='d')
{
if (type != 'h' && type != 'd') {
mylog(log_warn, "first byte is not h or d ,%x\n", type);
return -1;
}
char send_data_buf[buf_len]; // buf for send data and send hb
char send_data_buf2[buf_len];
@ -475,7 +415,6 @@ int send_safer(conn_info_t &conn_info,char type,const char* data,int len) //saf
memcpy(send_data_buf + sizeof(n_tmp_id) * 2, &n_seq, sizeof(n_seq));
send_data_buf[sizeof(n_tmp_id) * 2 + sizeof(n_seq)] = type;
send_data_buf[sizeof(n_tmp_id) * 2 + sizeof(n_seq) + 1] = conn_info.my_roller;
@ -483,33 +422,24 @@ int send_safer(conn_info_t &conn_info,char type,const char* data,int len) //saf
int new_len = len + sizeof(n_seq) + sizeof(n_tmp_id) * 2 + 2;
if(g_fix_gro==0)
{
if (my_encrypt(send_data_buf, send_data_buf2, new_len) != 0)
{
if (g_fix_gro == 0) {
if (my_encrypt(send_data_buf, send_data_buf2, new_len) != 0) {
return -1;
}
}
else
{
if (my_encrypt(send_data_buf, send_data_buf2+2, new_len) != 0)
{
} else {
if (my_encrypt(send_data_buf, send_data_buf2 + 2, new_len) != 0) {
return -1;
}
write_u16(send_data_buf2, new_len);
new_len += 2;
if(cipher_mode==cipher_xor)
{
if (cipher_mode == cipher_xor) {
send_data_buf2[0] ^= gro_xor[0];
send_data_buf2[1] ^= gro_xor[1];
}
else if(cipher_mode==cipher_aes128cbc||cipher_mode==cipher_aes128cbc)
{
} else if (cipher_mode == cipher_aes128cbc || cipher_mode == cipher_aes128cfb) {
aes_ecb_encrypt1(send_data_buf2);
}
}
if (send_raw0(conn_info.raw_info, send_data_buf2, new_len) != 0) return -1;
if (after_send_raw0(conn_info.raw_info) != 0) return -1;
@ -530,21 +460,17 @@ int send_data_safer(conn_info_t &conn_info,const char* data,int len,u32_t conv_n
int new_len = len + sizeof(n_conv_num);
send_safer(conn_info, 'd', send_data_buf, new_len);
return 0;
}
int reserved_parse_safer(conn_info_t &conn_info, const char *input, int input_len, char &type, char *&data, int &len) // subfunction for recv_safer,allow overlap
{
static char recv_data_buf[buf_len];
// char *recv_data_buf=recv_data_buf0; //fix strict alias warning
if(my_decrypt(input,recv_data_buf,input_len)!=0)
{
if (my_decrypt(input, recv_data_buf, input_len) != 0) {
// printf("decrypt fail\n");
return -1;
}
// char *a=recv_data_buf;
// id_t h_oppiste_id= ntohl ( *((id_t * )(recv_data_buf)) );
my_id_t h_oppsite_id;
@ -561,8 +487,7 @@ int reserved_parse_safer(conn_info_t &conn_info,const char * input,int input_len
memcpy(&h_seq, recv_data_buf + sizeof(my_id_t) * 2, sizeof(h_seq));
h_seq = ntoh64(h_seq);
if(h_oppsite_id!=conn_info.oppsite_id||h_my_id!=conn_info.my_id)
{
if (h_oppsite_id != conn_info.oppsite_id || h_my_id != conn_info.my_id) {
mylog(log_debug, "id and oppsite_id verification failed %x %x %x %x \n", h_oppsite_id, conn_info.oppsite_id, h_my_id, conn_info.my_id);
return -1;
}
@ -576,46 +501,37 @@ int reserved_parse_safer(conn_info_t &conn_info,const char * input,int input_len
data = recv_data_buf + sizeof(anti_replay_seq_t) + sizeof(my_id_t) * 2;
len = input_len - (sizeof(anti_replay_seq_t) + sizeof(my_id_t) * 2);
if(data[0]!='h'&&data[0]!='d')
{
if (data[0] != 'h' && data[0] != 'd') {
mylog(log_debug, "first byte is not h or d ,%x\n", data[0]);
return -1;
}
uint8_t roller = data[1];
type = data[0];
data += 2;
len -= 2;
if(len<0)
{
if (len < 0) {
mylog(log_debug, "len <0 ,%d\n", len);
return -1;
}
if(roller!=conn_info.oppsite_roller)
{
if (roller != conn_info.oppsite_roller) {
conn_info.oppsite_roller = roller;
conn_info.last_oppsite_roller_time = get_current_time();
}
if (hb_mode == 0)
conn_info.my_roller++; // increase on a successful recv
else if(hb_mode==1)
{
else if (hb_mode == 1) {
if (type == 'h')
conn_info.my_roller++;
}
else
{
} else {
mylog(log_fatal, "unknow hb_mode\n");
myexit(-1);
}
if(after_recv_raw0(conn_info.raw_info)!=0) return -1;
if (after_recv_raw0(conn_info.raw_info) != 0) return -1; // TODO might need to move this function to somewhere else after --fix-gro is introduced
return 0;
}
@ -624,7 +540,8 @@ int recv_safer_notused(conn_info_t &conn_info,char &type,char* &data,int &len)//
packet_info_t &send_info = conn_info.raw_info.send_info;
packet_info_t &recv_info = conn_info.raw_info.recv_info;
char * recv_data;int recv_len;
char *recv_data;
int recv_len;
// static char recv_data_buf[buf_len];
if (recv_raw0(conn_info.raw_info, recv_data, recv_len) != 0) return -1;
@ -637,7 +554,8 @@ int recv_safer_multi(conn_info_t &conn_info,vector<char> &type_arr,vector<string
packet_info_t &send_info = conn_info.raw_info.send_info;
packet_info_t &recv_info = conn_info.raw_info.recv_info;
char * recv_data;int recv_len;
char *recv_data;
int recv_len;
assert(type_arr.empty());
assert(data_arr.empty());
@ -647,55 +565,45 @@ int recv_safer_multi(conn_info_t &conn_info,vector<char> &type_arr,vector<string
char *data;
int len;
if(g_fix_gro==0)
{
if (g_fix_gro == 0) {
int ret = reserved_parse_safer(conn_info, recv_data, recv_len, type, data, len);
if(ret==0)
{
if (ret == 0) {
type_arr.push_back(type);
data_arr.emplace_back(data, data + len);
// std::copy(data,data+len,data_arr[0]);
}
return 0;
} else
{
} else {
char *ori_recv_data = recv_data;
int ori_recv_len = recv_len;
// mylog(log_debug,"recv_len:%d\n",recv_len);
int cnt = 0;
while(recv_len>=16)
{
while (recv_len >= 16) {
cnt++;
int single_len_no_xor;
single_len_no_xor = read_u16(recv_data);
int single_len;
if(cipher_mode==cipher_xor)
{
if (cipher_mode == cipher_xor) {
recv_data[0] ^= gro_xor[0];
recv_data[1] ^= gro_xor[1];
}
else if(cipher_mode==cipher_aes128cbc||cipher_mode==cipher_aes128cbc)
{
} else if (cipher_mode == cipher_aes128cbc || cipher_mode == cipher_aes128cfb) {
aes_ecb_decrypt1(recv_data);
}
single_len = read_u16(recv_data);
recv_len -= 2;
recv_data += 2;
if(single_len > recv_len)
{
if (single_len > recv_len) {
mylog(log_debug, "illegal single_len %d(%d), recv_len %d left,dropped\n", single_len, single_len_no_xor, recv_len);
break;
}
if(single_len> max_data_len )
{
if (single_len > max_data_len) {
mylog(log_warn, "single_len %d(%d) > %d, maybe you need to turn down mtu at upper level\n", single_len, single_len_no_xor, max_data_len);
break;
}
int ret = reserved_parse_safer(conn_info, recv_data, single_len, type, data, len);
if(ret!=0)
{
if (ret != 0) {
mylog(log_debug, "parse failed, offset= %d,single_len=%d(%d)\n", (int)(recv_data - ori_recv_data), single_len, single_len_no_xor);
} else {
type_arr.push_back(type);
@ -705,15 +613,13 @@ int recv_safer_multi(conn_info_t &conn_info,vector<char> &type_arr,vector<string
recv_data += single_len;
recv_len -= single_len;
}
if(cnt>1)
{
if (cnt > 1) {
mylog(log_debug, "got a suspected gro packet, %d packets recovered, recv_len=%d, loop_cnt=%d\n", (int)data_arr.size(), ori_recv_len, cnt);
}
return 0;
}
}
void server_clear_function(u64_t u64) // used in conv_manager in server mode.for server we have to use one udp fd for one conv(udp connection),
// so we have to close the fd when conv expires
{
@ -731,7 +637,8 @@ void server_clear_function(u64_t u64)//used in conv_manager in server mode.for s
{
mylog(log_fatal,"fd:%d epoll delete failed!!!!\n",fd);
myexit(-1); //this shouldnt happen
}*/ //no need
}*/
// no need
/*ret= close(fd); //closed fd should be auto removed from epoll

96
connection.h
View File

@ -50,36 +50,29 @@ struct conv_manager_t // manage the udp connections
long long last_clear_time;
conv_manager_t()
{
conv_manager_t() {
// clear_it=conv_last_active_time.begin();
long long last_clear_time = 0;
additional_clear_function = 0;
}
~conv_manager_t()
{
~conv_manager_t() {
clear();
}
int get_size()
{
int get_size() {
return conv_to_data.size();
}
void reserve()
{
void reserve() {
data_to_conv.reserve(10007);
conv_to_data.reserve(10007);
// conv_last_active_time.reserve(10007);
lru.mp.reserve(10007);
}
void clear()
{
void clear() {
if (disable_conv_clear) return;
if(additional_clear_function!=0)
{
for(auto it=conv_to_data.begin();it!=conv_to_data.end();it++)
{
if (additional_clear_function != 0) {
for (auto it = conv_to_data.begin(); it != conv_to_data.end(); it++) {
// int fd=int((it->second<<32u)>>32u);
additional_clear_function(it->second);
}
@ -91,53 +84,42 @@ struct conv_manager_t // manage the udp connections
// conv_last_active_time.clear();
// clear_it=conv_last_active_time.begin();
}
u32_t get_new_conv()
{
u32_t get_new_conv() {
u32_t conv = get_true_random_number_nz();
while(conv_to_data.find(conv)!=conv_to_data.end())
{
while (conv_to_data.find(conv) != conv_to_data.end()) {
conv = get_true_random_number_nz();
}
return conv;
}
int is_conv_used(u32_t conv)
{
int is_conv_used(u32_t conv) {
return conv_to_data.find(conv) != conv_to_data.end();
}
int is_data_used(T data)
{
int is_data_used(T data) {
return data_to_conv.find(data) != data_to_conv.end();
}
u32_t find_conv_by_data(T data)
{
u32_t find_conv_by_data(T data) {
return data_to_conv[data];
}
T find_data_by_conv(u32_t conv)
{
T find_data_by_conv(u32_t conv) {
return conv_to_data[conv];
}
int update_active_time(u32_t conv)
{
int update_active_time(u32_t conv) {
// return conv_last_active_time[conv]=get_current_time();
lru.update(conv);
return 0;
}
int insert_conv(u32_t conv,T data)
{
int insert_conv(u32_t conv, T data) {
data_to_conv[data] = conv;
conv_to_data[conv] = data;
// conv_last_active_time[conv]=get_current_time();
lru.new_key(conv);
return 0;
}
int erase_conv(u32_t conv)
{
int erase_conv(u32_t conv) {
if (disable_conv_clear) return 0;
T data = conv_to_data[conv];
if(additional_clear_function!=0)
{
if (additional_clear_function != 0) {
additional_clear_function(data);
}
conv_to_data.erase(conv);
@ -146,20 +128,16 @@ struct conv_manager_t // manage the udp connections
lru.erase(conv);
return 0;
}
int clear_inactive(char * info=0)
{
if(get_current_time()-last_clear_time>conv_clear_interval)
{
int clear_inactive(char *info = 0) {
if (get_current_time() - last_clear_time > conv_clear_interval) {
last_clear_time = get_current_time();
return clear_inactive0(info);
}
return 0;
}
int clear_inactive0(char * info)
{
int clear_inactive0(char *info) {
if (disable_conv_clear) return 0;
unordered_map<u32_t, u64_t>::iterator it;
unordered_map<u32_t, u64_t>::iterator old_it;
@ -172,8 +150,7 @@ struct conv_manager_t // manage the udp connections
num_to_clean = min(num_to_clean, size);
my_time_t current_time = get_current_time();
for(;;)
{
for (;;) {
if (cnt >= num_to_clean) break;
if (lru.empty()) break;
@ -183,12 +160,9 @@ struct conv_manager_t // manage the udp connections
if (current_time - ts < conv_timeout) break;
erase_conv(conv);
if(info==0)
{
if (info == 0) {
mylog(log_info, "conv %x cleared\n", conv);
}
else
{
} else {
mylog(log_info, "[%s]conv %x cleared\n", info, conv);
}
cnt++;
@ -196,7 +170,6 @@ struct conv_manager_t // manage the udp connections
return 0;
}
/*
conv_manager_t();
~conv_manager_t();
@ -222,26 +195,18 @@ struct blob_t:not_copy_able_t //used in conn_info_t.
conv_manager_t<address_t> c;
conv_manager_t<u64_t> s;
// avoid templates here and there, avoid pointer and type cast
tmp_union_t()
{
if(program_mode==client_mode)
{
tmp_union_t() {
if (program_mode == client_mode) {
new (&c) conv_manager_t<address_t>();
}
else
{
} else {
assert(program_mode == server_mode);
new (&s) conv_manager_t<u64_t>();
}
}
~tmp_union_t()
{
if(program_mode==client_mode)
{
~tmp_union_t() {
if (program_mode == client_mode) {
c.~conv_manager_t<address_t>();
}
else
{
} else {
assert(program_mode == server_mode);
s.~conv_manager_t<u64_t>();
}
@ -264,7 +229,6 @@ struct conn_info_t //stores info for a raw connection.for client ,there is o
my_id_t my_id;
my_id_t oppsite_id;
fd64_t timer_fd64;
fd64_t udp_fd64;
@ -294,7 +258,6 @@ struct conn_info_t //stores info for a raw connection.for client ,there is o
struct conn_manager_t // manager for connections. for client,we dont need conn_manager since there is only one connection.for server we use one conn_manager for all connections
{
u32_t ready_num;
// unordered_map<int,conn_info_t *> udp_fd_mp; //a bit dirty to used pointer,but can void unordered_map search
@ -328,7 +291,6 @@ struct conn_manager_t //manager for connections. for client,we dont need conn_m
int erase(unordered_map<address_t, conn_info_t *>::iterator erase_it);
int clear_inactive();
int clear_inactive0();
};
extern conn_manager_t conn_manager;

35
doc/README.zh-cn.md
View File

@ -14,21 +14,19 @@ udp2raw tunnel通过raw socket给UDP包加上TCP或ICMP header进而绕过
**提示:**
udp2raw不是加速器只是一个帮助你绕过UDP限制的工具。如果你需要UDP加速器请看UDPspeeder。
udp2raw不是加速器只是一个帮助你绕过UDP限制的工具。如果你需要UDP加速器” (改善UDP丢包)请看UDPspeeder。
UDPspeeder的repo:
https://github.com/wangyu-/UDPspeeder
# 支持的平台
Linux主机有root权限。可以是PC、android手机/平板、openwrt路由器、树莓派。主机上最好安装了iptables命令(apt/yum很容易安装)。
Linux主机有root权限或cap_net_raw capability.。可以是PC、android手机/平板、openwrt路由器、树莓派。主机上最好安装了iptables命令(apt/yum很容易安装)。
Release中提供了`amd64`、`x86`、`arm`、`mips_be`、`mips_le`的预编译binary.
##### 对于windows和mac用户
可以用[这个repo](https://github.com/wangyu-/udp2raw-multiplatform)里的udp2raw原生运行。
<del>可以把udp2raw运行在虚拟机上(网络必须是桥接模式)。可以参考: https://github.com/wangyu-/udp2raw-tunnel/wiki/在windows-mac上运行udp2raw客户端带图形界面 </del>
可以用[这个repo](https://github.com/wangyu-/udp2raw-multiplatform)里的udp2raw。
##### 对于ios和游戏主机用户
@ -44,10 +42,10 @@ Release中提供了`amd64`、`x86`、`arm`、`mips_be`、`mips_le`的预编译bi
### 心跳保活、自动重连,连接恢复
心跳保活、自动重连udp2raw重连可以恢复上次的连接重连后上层连接继续有效底层掉线上层不掉线。有效解决上层连接断开的问题。 (功能借鉴自[kcptun-raw](https://github.com/Chion82/kcptun-raw)**就算你拔掉网线重插或者重新拨号获得新ip上层应用也不会断线**
### 加密 防重放攻击
### 加密防重放攻击
用aes128cbc加密(或更弱的xor)hmac-sha1(或更弱的md5/crc32/simple)做数据完整校验。用类似ipsec/openvpn的replay window机制来防止重放攻击。
设计目标是即使攻击者可以监听到tunnel的所有包可以选择性丢弃tunnel的任意包可以重放任意包攻击者也没办法获得tunnel承载的任何数据也没办法向tunnel的数据流中通过包构造/包重放插入任何数据。
[Notes on encryption](https://github.com/wangyu-/udp2raw-tunnel/wiki/Notes-on-encryption)
### 其他特性
信道复用client的udp端支持多个连接。
@ -56,7 +54,7 @@ server支持多个client也能正确处理多个连接的重连和连接恢
NAT 穿透 tcp icmp udp模式都支持nat穿透。
支持Openvz配合finalspeed使用可以在openvz上用tcp模式的finalspeed
支持Openvz配合finalspeed使用可以在openvz上用tcp模式的finalspeed.
支持Openwrt没有编译依赖容易编译到任何平台上。
@ -163,7 +161,7 @@ other options:
如果要最大的安全性建议用aes128cbc+hmac_sha1。如果要运行在路由器上建议用xor+simple可以节省CPU。但是注意xor+simple只能骗过防火墙的包检测不能防止真正的攻击者。
### `--seq-mode`
facktcp模式并没有模拟tcp的全部。所以理论上有办法把faketcp和真正的tcp流量区分开来虽然大部分ISP不太可能做这种程度的包检测。seq-mode可以改变一些seq ack的行为。如果遇到了连接问题可以尝试更改。在我这边的移动线路用3种模式都没问题。
faketcp模式并没有模拟tcp的全部。所以理论上有办法把faketcp和真正的tcp流量区分开来虽然大部分ISP不太可能做这种程度的包检测。seq-mode可以改变一些seq ack的行为。如果遇到了连接问题可以尝试更改。在我这边的移动线路用3种模式都没问题。
### `--keep-rule`
定期主动检查iptables如果udp2raw添加的iptables规则丢了就重新添加。在一些iptables可能会被其他程序清空的情况下(比如梅林固件和openwrt的路由器)格外有用。
@ -264,25 +262,6 @@ raw_mode: faketcp cipher_mode: aes128cbc  auth_mode: md5
[udp2raw+kcptun step_by_step教程](kcptun_step_by_step.md)
### 中转 finalspeed
[udp2raw+finalspeed step_by_step教程](finalspeed_step_by_step.md)
# 如何自己编译
[编译教程](build_guide.zh-cn.md)
# 相关repo
### kcptun-raw
udp2raw was inspired by kcptun-raw,which modified kcptun to support tcp mode.
https://github.com/Chion82/kcptun-raw
### relayRawSocket
kcptun-raw was inspired by relayRawSocket. A simple udp to raw tunnel,wrote in python
https://github.com/linhua55/some_kcptun_tools/tree/master/relayRawSocket
### kcpraw
another project of kcptun with tcp mode
https://github.com/ccsexyz/kcpraw
### icmptunnel
Transparently tunnel your IP traffic through ICMP echo and reply packets.
https://github.com/DhavalKapil/icmptunnel
# wiki

364
encrypt.cpp Executable file → Normal file
View File

@ -28,9 +28,20 @@ unsigned char cipher_key_decrypt[cipher_key_len + 100]; //key for aes etc.
char gro_xor[256 + 100]; // dirty fix for gro
unordered_map<int, const char *> auth_mode_tostring = {{auth_none, "none"}, {auth_md5, "md5"}, {auth_crc32, "crc32"},{auth_simple,"simple"},{auth_hmac_sha1,"hmac_sha1"},};
unordered_map<int, const char *> auth_mode_tostring = {
{auth_none, "none"},
{auth_md5, "md5"},
{auth_crc32, "crc32"},
{auth_simple, "simple"},
{auth_hmac_sha1, "hmac_sha1"},
};
unordered_map<int, const char *> cipher_mode_tostring={{cipher_none,"none"},{cipher_aes128cfb,"aes128cfb"},{cipher_aes128cbc,"aes128cbc"},{cipher_xor,"xor"},};
unordered_map<int, const char *> cipher_mode_tostring = {
{cipher_none, "none"},
{cipher_aes128cfb, "aes128cfb"},
{cipher_aes128cbc, "aes128cbc"},
{cipher_xor, "xor"},
};
// TODO aes-gcm
auth_mode_t auth_mode = auth_md5;
@ -41,8 +52,7 @@ int aes128cfb_old=0;
// TODO key negotiation and forward secrecy
int my_init_keys(const char * user_passwd,int is_client)
{
int my_init_keys(const char *user_passwd, int is_client) {
char tmp[1000] = "";
int len = strlen(user_passwd);
@ -52,11 +62,9 @@ int my_init_keys(const char * user_passwd,int is_client)
md5((uint8_t *)tmp, strlen(tmp), (uint8_t *)normal_key);
if (auth_mode == auth_hmac_sha1)
is_hmac_used = 1;
if(is_hmac_used||g_fix_gro||1)
{
if (is_hmac_used || g_fix_gro || 1) {
unsigned char salt[400] = "";
char salt_text[400] = "udp2raw_salt1";
md5((uint8_t *)(salt_text), strlen(salt_text), salt); // TODO different salt per session
@ -72,14 +80,15 @@ int my_init_keys(const char * user_passwd,int is_client)
const char *info_cipher_encrypt = "cipher_key server-->client";
const char *info_cipher_decrypt = "cipher_key client-->server";
if(is_client)
{
if (is_client) {
const char *tmp;
tmp=info_hmac_encrypt; info_hmac_encrypt=info_hmac_decrypt;info_hmac_decrypt=tmp;
tmp=info_cipher_encrypt; info_cipher_encrypt=info_cipher_decrypt;info_cipher_decrypt=tmp;
}
else
{
tmp = info_hmac_encrypt;
info_hmac_encrypt = info_hmac_decrypt;
info_hmac_decrypt = tmp;
tmp = info_cipher_encrypt;
info_cipher_encrypt = info_cipher_decrypt;
info_cipher_decrypt = tmp;
} else {
// nop
}
@ -143,8 +152,7 @@ void simple_hash(unsigned char *str,int len,unsigned char res[8]) //djb2+ sdbm
u32_t hash2 = 0;
int c;
int i = 0;
while(c = *str++,i++!=len)
{
while (c = *str++, i++ != len) {
// hash = ((hash << 5) + hash) + c; /* hash * 33 + c */
hash = ((hash << 5) + hash) ^ c; /* (hash * 33) ^ c */
hash2 = c + (hash2 << 6) + (hash2 << 16) - hash2;
@ -156,16 +164,14 @@ void simple_hash(unsigned char *str,int len,unsigned char res[8]) //djb2+ sdbm
memcpy(res + sizeof(hash), &hash2, sizeof(hash2));
}
int auth_md5_cal(const char *data,char * output,int &len)
{
int auth_md5_cal(const char *data, char *output, int &len) {
memcpy(output, data, len); // TODO inefficient code
md5((unsigned char *)output, len, (unsigned char *)(output + len));
len += 16;
return 0;
}
int auth_hmac_sha1_cal(const char *data,char * output,int &len)
{
int auth_hmac_sha1_cal(const char *data, char *output, int &len) {
mylog(log_trace, "auth_hmac_sha1_cal() is called\n");
memcpy(output, data, len); // TODO inefficient code
sha1_hmac(hmac_key_encrypt, 20, (const unsigned char *)data, len, (unsigned char *)(output + len));
@ -174,11 +180,9 @@ int auth_hmac_sha1_cal(const char *data,char * output,int &len)
return 0;
}
int auth_hmac_sha1_verify(const char *data,int &len)
{
int auth_hmac_sha1_verify(const char *data, int &len) {
mylog(log_trace, "auth_hmac_sha1_verify() is called\n");
if(len<20)
{
if (len < 20) {
mylog(log_trace, "auth_hmac_sha1_verify len<20\n");
return -1;
}
@ -186,8 +190,7 @@ int auth_hmac_sha1_verify(const char *data,int &len)
sha1_hmac(hmac_key_decrypt, 20, (const unsigned char *)data, len - 20, (unsigned char *)(res));
if(memcmp(res,data+len-20,20)!=0)
{
if (memcmp(res, data + len - 20, 20) != 0) {
mylog(log_trace, "auth_hmac_sha1 check failed\n");
return -2;
}
@ -195,8 +198,7 @@ int auth_hmac_sha1_verify(const char *data,int &len)
return 0;
}
int auth_crc32_cal(const char *data,char * output,int &len)
{
int auth_crc32_cal(const char *data, char *output, int &len) {
memcpy(output, data, len); // TODO inefficient code
unsigned int ret = crc32h((unsigned char *)output, len);
unsigned int ret_n = htonl(ret);
@ -205,16 +207,14 @@ int auth_crc32_cal(const char *data,char * output,int &len)
return 0;
}
int auth_simple_cal(const char *data,char * output,int &len)
{
int auth_simple_cal(const char *data, char *output, int &len) {
// char res[4];
memcpy(output, data, len); // TODO inefficient code
simple_hash((unsigned char *)output, len, (unsigned char *)(output + len));
len += 8;
return 0;
}
int auth_simple_verify(const char *data,int &len)
{
int auth_simple_verify(const char *data, int &len) {
if (len < 8) return -1;
unsigned char res[8];
len -= 8;
@ -224,16 +224,12 @@ int auth_simple_verify(const char *data,int &len)
return 0;
}
int auth_none_cal(const char *data,char * output,int &len)
{
int auth_none_cal(const char *data, char *output, int &len) {
memcpy(output, data, len);
return 0;
}
int auth_md5_verify(const char *data,int &len)
{
if(len<16)
{
int auth_md5_verify(const char *data, int &len) {
if (len < 16) {
mylog(log_trace, "auth_md5_verify len<16\n");
return -1;
}
@ -241,16 +237,14 @@ int auth_md5_verify(const char *data,int &len)
md5((unsigned char *)data, len - 16, (unsigned char *)md5_res);
if(memcmp(md5_res,data+len-16,16)!=0)
{
if (memcmp(md5_res, data + len - 16, 16) != 0) {
mylog(log_trace, "auth_md5_verify md5 check failed\n");
return -2;
}
len -= 16;
return 0;
}
int auth_none_verify(const char *data,int &len)
{
int auth_none_verify(const char *data, int &len) {
return 0;
}
@ -276,12 +270,10 @@ int cipher_xor_decrypt(const char * data, char *output,int &len, char *key) {
return 0;
}
int padding(char *data ,int &data_len,int padding_num)
{
int padding(char *data, int &data_len, int padding_num) {
int old_len = data_len;
data_len += 1;
if(data_len%padding_num!=0)
{
if (data_len % padding_num != 0) {
data_len = (data_len / padding_num) * padding_num + padding_num;
}
unsigned char *p = (unsigned char *)&data[data_len - 1];
@ -289,52 +281,48 @@ int padding(char *data ,int &data_len,int padding_num)
return 0;
}
int de_padding(const char *data ,int &data_len,int padding_num)
{
int de_padding(const char *data, int &data_len, int padding_num) {
if (data_len == 0) return -1;
if ((uint8_t)data[data_len - 1] > padding_num) return -1;
data_len -= (uint8_t)data[data_len - 1];
if(data_len<0)
{
if (data_len < 0) {
return -1;
}
return 0;
}
void aes_ecb_encrypt(const char *data,char *output)
{
void aes_ecb_encrypt(const char *data, char *output) {
static int first_time = 1;
char *key = (char *)cipher_key_encrypt;
if(aes_key_optimize)
{
if(first_time==0) key=0;
else first_time=0;
if (aes_key_optimize) {
if (first_time == 0)
key = 0;
else
first_time = 0;
}
AES_ECB_encrypt_buffer((uint8_t *)data, (uint8_t *)key, (uint8_t *)output);
}
void aes_ecb_encrypt1(char *data)
{
void aes_ecb_encrypt1(char *data) {
char buf[16];
memcpy(buf, data, 16);
aes_ecb_encrypt(buf, data);
}
void aes_ecb_decrypt(const char *data,char *output)
{
void aes_ecb_decrypt(const char *data, char *output) {
static int first_time = 1;
char *key = (char *)cipher_key_decrypt;
if(aes_key_optimize)
{
if(first_time==0) key=0;
else first_time=0;
if (aes_key_optimize) {
if (first_time == 0)
key = 0;
else
first_time = 0;
}
AES_ECB_decrypt_buffer((uint8_t *)data, (uint8_t *)key, (uint8_t *)output);
}
void aes_ecb_decrypt1(char *data)
{
void aes_ecb_decrypt1(char *data) {
char buf[16];
memcpy(buf, data, 16);
aes_ecb_decrypt(buf, data);
}
int cipher_aes128cbc_encrypt(const char *data,char *output,int &len,char * key)
{
int cipher_aes128cbc_encrypt(const char *data, char *output, int &len, char *key) {
static int first_time = 1;
char buf[buf_len];
@ -342,83 +330,81 @@ int cipher_aes128cbc_encrypt(const char *data,char *output,int &len,char * key)
if (padding(buf, len, 16) < 0) return -1;
if(aes_key_optimize)
{
if(first_time==0) key=0;
else first_time=0;
if (aes_key_optimize) {
if (first_time == 0)
key = 0;
else
first_time = 0;
}
AES_CBC_encrypt_buffer((unsigned char *)output, (unsigned char *)buf, len, (unsigned char *)key, (unsigned char *)zero_iv);
return 0;
}
int cipher_aes128cfb_encrypt(const char *data,char *output,int &len,char * key)
{
int cipher_aes128cfb_encrypt(const char *data, char *output, int &len, char *key) {
static int first_time = 1;
assert(len >= 16);
char buf[buf_len];
memcpy(buf, data, len); // TODO inefficient code
if(aes_key_optimize)
{
if(first_time==0) key=0;
else first_time=0;
if (aes_key_optimize) {
if (first_time == 0)
key = 0;
else
first_time = 0;
}
if(!aes128cfb_old)
{
if (!aes128cfb_old) {
aes_ecb_encrypt(data, buf); // encrypt the first block
}
AES_CFB_encrypt_buffer((unsigned char *)output, (unsigned char *)buf, len, (unsigned char *)key, (unsigned char *)zero_iv);
return 0;
}
int auth_crc32_verify(const char *data,int &len)
{
if(len<int(sizeof(unsigned int)))
{
int auth_crc32_verify(const char *data, int &len) {
if (len < int(sizeof(unsigned int))) {
mylog(log_debug, "auth_crc32_verify len<%d\n", int(sizeof(unsigned int)));
return -1;
}
unsigned int ret = crc32h((unsigned char *)data, len - sizeof(unsigned int));
unsigned int ret_n = htonl(ret);
if(memcmp(data+len-sizeof(unsigned int),&ret_n,sizeof(unsigned int))!=0)
{
if (memcmp(data + len - sizeof(unsigned int), &ret_n, sizeof(unsigned int)) != 0) {
mylog(log_debug, "auth_crc32_verify memcmp fail\n");
return -1;
}
len -= sizeof(unsigned int);
return 0;
}
int cipher_none_encrypt(const char *data,char *output,int &len,char * key)
{
int cipher_none_encrypt(const char *data, char *output, int &len, char *key) {
memcpy(output, data, len);
return 0;
}
int cipher_aes128cbc_decrypt(const char *data,char *output,int &len,char * key)
{
int cipher_aes128cbc_decrypt(const char *data, char *output, int &len, char *key) {
static int first_time = 1;
if(len%16 !=0) {mylog(log_debug,"len%%16!=0\n");return -1;}
if(aes_key_optimize)
{
if(first_time==0) key=0;
else first_time=0;
if (len % 16 != 0) {
mylog(log_debug, "len%%16!=0\n");
return -1;
}
if (aes_key_optimize) {
if (first_time == 0)
key = 0;
else
first_time = 0;
}
AES_CBC_decrypt_buffer((unsigned char *)output, (unsigned char *)data, len, (unsigned char *)key, (unsigned char *)zero_iv);
if (de_padding(output, len, 16) < 0) return -1;
return 0;
}
int cipher_aes128cfb_decrypt(const char *data,char *output,int &len,char * key)
{
int cipher_aes128cfb_decrypt(const char *data, char *output, int &len, char *key) {
static int first_time = 1;
if (len < 16) return -1;
if(aes_key_optimize)
{
if(first_time==0) key=0;
else first_time=0;
if (aes_key_optimize) {
if (first_time == 0)
key = 0;
else
first_time = 0;
}
AES_CFB_decrypt_buffer((unsigned char *)output, (unsigned char *)data, len, (unsigned char *)key, (unsigned char *)zero_iv);
if (!aes128cfb_old)
@ -427,81 +413,97 @@ int cipher_aes128cfb_decrypt(const char *data,char *output,int &len,char * key)
return 0;
}
int cipher_none_decrypt(const char *data,char *output,int &len,char * key)
{
int cipher_none_decrypt(const char *data, char *output, int &len, char *key) {
memcpy(output, data, len);
return 0;
}
int auth_cal(const char *data,char * output,int &len)
{
int auth_cal(const char *data, char *output, int &len) {
mylog(log_trace, "auth:%d\n", auth_mode);
switch(auth_mode)
{
case auth_crc32:return auth_crc32_cal(data, output, len);
case auth_md5:return auth_md5_cal(data, output, len);
case auth_simple:return auth_simple_cal(data, output, len);
case auth_none:return auth_none_cal(data, output, len);
case auth_hmac_sha1:return auth_hmac_sha1_cal(data,output,len);
switch (auth_mode) {
case auth_crc32:
return auth_crc32_cal(data, output, len);
case auth_md5:
return auth_md5_cal(data, output, len);
case auth_simple:
return auth_simple_cal(data, output, len);
case auth_none:
return auth_none_cal(data, output, len);
case auth_hmac_sha1:
return auth_hmac_sha1_cal(data, output, len);
// default: return auth_md5_cal(data,output,len);//default;
default: assert(0==1);
default:
assert(0 == 1);
}
return -1;
}
int auth_verify(const char *data,int &len)
{
int auth_verify(const char *data, int &len) {
mylog(log_trace, "auth:%d\n", auth_mode);
switch(auth_mode)
{
case auth_crc32:return auth_crc32_verify(data, len);
case auth_md5:return auth_md5_verify(data, len);
case auth_simple:return auth_simple_verify(data, len);
case auth_none:return auth_none_verify(data, len);
case auth_hmac_sha1:return auth_hmac_sha1_verify(data,len);
switch (auth_mode) {
case auth_crc32:
return auth_crc32_verify(data, len);
case auth_md5:
return auth_md5_verify(data, len);
case auth_simple:
return auth_simple_verify(data, len);
case auth_none:
return auth_none_verify(data, len);
case auth_hmac_sha1:
return auth_hmac_sha1_verify(data, len);
// default: return auth_md5_verify(data,len);//default
default: assert(0==1);
default:
assert(0 == 1);
}
return -1;
}
int cipher_encrypt(const char *data,char *output,int &len,char * key)
{
int cipher_encrypt(const char *data, char *output, int &len, char *key) {
mylog(log_trace, "cipher:%d\n", cipher_mode);
switch(cipher_mode)
{
case cipher_aes128cbc:return cipher_aes128cbc_encrypt(data,output,len, key);
case cipher_aes128cfb:return cipher_aes128cfb_encrypt(data,output,len, key);
case cipher_xor:return cipher_xor_encrypt(data,output,len, key);
case cipher_none:return cipher_none_encrypt(data,output,len, key);
switch (cipher_mode) {
case cipher_aes128cbc:
return cipher_aes128cbc_encrypt(data, output, len, key);
case cipher_aes128cfb:
return cipher_aes128cfb_encrypt(data, output, len, key);
case cipher_xor:
return cipher_xor_encrypt(data, output, len, key);
case cipher_none:
return cipher_none_encrypt(data, output, len, key);
// default:return cipher_aes128cbc_encrypt(data,output,len, key);
default: assert(0==1);
default:
assert(0 == 1);
}
return -1;
}
int cipher_decrypt(const char *data,char *output,int &len,char * key)
{
int cipher_decrypt(const char *data, char *output, int &len, char *key) {
mylog(log_trace, "cipher:%d\n", cipher_mode);
switch(cipher_mode)
{
case cipher_aes128cbc:return cipher_aes128cbc_decrypt(data,output,len, key);
case cipher_aes128cfb:return cipher_aes128cfb_decrypt(data,output,len, key);
case cipher_xor:return cipher_xor_decrypt(data,output,len, key);
case cipher_none:return cipher_none_decrypt(data,output,len, key);
switch (cipher_mode) {
case cipher_aes128cbc:
return cipher_aes128cbc_decrypt(data, output, len, key);
case cipher_aes128cfb:
return cipher_aes128cfb_decrypt(data, output, len, key);
case cipher_xor:
return cipher_xor_decrypt(data, output, len, key);
case cipher_none:
return cipher_none_decrypt(data, output, len, key);
// default: return cipher_aes128cbc_decrypt(data,output,len,key);
default: assert(0==1);
default:
assert(0 == 1);
}
return -1;
}
int encrypt_AE(const char *data,char *output,int &len /*,char * key*/)
{
int encrypt_AE(const char *data, char *output, int &len /*,char * key*/) {
mylog(log_trace, "encrypt_AE is called\n");
char buf[buf_len];
char buf2[buf_len];
memcpy(buf, data, len);
if(cipher_encrypt(buf,buf2,len,(char *)cipher_key_encrypt) !=0) {mylog(log_debug,"cipher_encrypt failed ");return -1;}
if(auth_cal(buf2,output,len)!=0) {mylog(log_debug,"auth_cal failed ");return -1;}
if (cipher_encrypt(buf, buf2, len, (char *)cipher_key_encrypt) != 0) {
mylog(log_debug, "cipher_encrypt failed ");
return -1;
}
if (auth_cal(buf2, output, len) != 0) {
mylog(log_debug, "auth_cal failed ");
return -1;
}
// printf("%d %x %x\n",len,(int)(output[0]),(int)(output[1]));
// print_binary_chars(output,len);
@ -510,59 +512,77 @@ int encrypt_AE(const char *data,char *output,int &len /*,char * key*/)
return 0;
}
int decrypt_AE(const char *data,char *output,int &len /*,char * key*/)
{
int decrypt_AE(const char *data, char *output, int &len /*,char * key*/) {
mylog(log_trace, "decrypt_AE is called\n");
// printf("%d %x %x\n",len,(int)(data[0]),(int)(data[1]));
// print_binary_chars(data,len);
if(auth_verify(data,len)!=0) {mylog(log_debug,"auth_verify failed\n");return -1;}
if(cipher_decrypt(data,output,len,(char *)cipher_key_decrypt) !=0) {mylog(log_debug,"cipher_decrypt failed \n"); return -1;}
if (auth_verify(data, len) != 0) {
mylog(log_debug, "auth_verify failed\n");
return -1;
}
if (cipher_decrypt(data, output, len, (char *)cipher_key_decrypt) != 0) {
mylog(log_debug, "cipher_decrypt failed \n");
return -1;
}
return 0;
}
int my_encrypt(const char *data,char *output,int &len /*,char * key*/)
{
if(len<0) {mylog(log_trace,"len<0");return -1;}
if(len>max_data_len) {mylog(log_warn,"len>max_data_len");return -1;}
int my_encrypt(const char *data, char *output, int &len /*,char * key*/) {
if (len < 0) {
mylog(log_trace, "len<0");
return -1;
}
if (len > max_data_len) {
mylog(log_warn, "len>max_data_len");
return -1;
}
if (is_hmac_used)
return encrypt_AE(data, output, len);
char buf[buf_len];
char buf2[buf_len];
memcpy(buf, data, len);
if(auth_cal(buf,buf2,len)!=0) {mylog(log_debug,"auth_cal failed ");return -1;}
if(cipher_encrypt(buf2,output,len,normal_key) !=0) {mylog(log_debug,"cipher_encrypt failed ");return -1;}
if (auth_cal(buf, buf2, len) != 0) {
mylog(log_debug, "auth_cal failed ");
return -1;
}
if (cipher_encrypt(buf2, output, len, normal_key) != 0) {
mylog(log_debug, "cipher_encrypt failed ");
return -1;
}
return 0;
}
int my_decrypt(const char *data,char *output,int &len /*,char * key*/)
{
int my_decrypt(const char *data, char *output, int &len /*,char * key*/) {
if (len < 0) return -1;
if(len>max_data_len) {mylog(log_warn,"len>max_data_len");return -1;}
if (len > max_data_len) {
mylog(log_warn, "len>max_data_len");
return -1;
}
if (is_hmac_used)
return decrypt_AE(data, output, len);
if(cipher_decrypt(data,output,len,normal_key) !=0) {mylog(log_debug,"cipher_decrypt failed \n"); return -1;}
if(auth_verify(output,len)!=0) {mylog(log_debug,"auth_verify failed\n");return -1;}
if (cipher_decrypt(data, output, len, normal_key) != 0) {
mylog(log_debug, "cipher_decrypt failed \n");
return -1;
}
if (auth_verify(output, len) != 0) {
mylog(log_debug, "auth_verify failed\n");
return -1;
}
return 0;
}
int encrypt_AEAD(uint8_t *data,uint8_t *output,int &len,uint8_t * key,uint8_t *header,int hlen)
{
int encrypt_AEAD(uint8_t *data, uint8_t *output, int &len, uint8_t *key, uint8_t *header, int hlen) {
// TODO
return -1;
}
int decrypt_AEAD(uint8_t *data,uint8_t *output,int &len,uint8_t * key,uint8_t *header,int hlen)
{
int decrypt_AEAD(uint8_t *data, uint8_t *output, int &len, uint8_t *key, uint8_t *header, int hlen) {
// TODO
return -1;
}

20
encrypt.h Executable file → Normal file
View File

@ -1,13 +1,10 @@
#ifndef UDP2RAW_ENCRYPTION_H_
#define UDP2RAW_ENCRYPTION_H_
//#include "aes.h"
//#include "md5.h"
#include "common.h"
// using namespace std;
// extern char key[16];
@ -19,15 +16,20 @@ int my_init_keys(const char *,int);
int my_encrypt(const char *data, char *output, int &len);
int my_decrypt(const char *data, char *output, int &len);
unsigned short csum(const unsigned short *ptr, int nbytes);
enum auth_mode_t { auth_none = 0,
auth_md5,
auth_crc32,
auth_simple,
auth_hmac_sha1,
auth_end };
enum auth_mode_t {auth_none=0,auth_md5,auth_crc32,auth_simple,auth_hmac_sha1,auth_end};
enum cipher_mode_t {cipher_none=0,cipher_aes128cbc,cipher_xor,cipher_aes128cfb,cipher_end};
enum cipher_mode_t { cipher_none = 0,
cipher_aes128cbc,
cipher_xor,
cipher_aes128cfb,
cipher_end };
extern auth_mode_t auth_mode;
extern cipher_mode_t cipher_mode;

31
fd_manager.cpp
View File

@ -5,60 +5,49 @@
* Author: root
*/
#include "fd_manager.h"
int fd_manager_t::fd_exist(int fd)
{
int fd_manager_t::fd_exist(int fd) {
return fd_to_fd64_mp.find(fd) != fd_to_fd64_mp.end();
}
int fd_manager_t::exist(fd64_t fd64)
{
int fd_manager_t::exist(fd64_t fd64) {
return fd64_to_fd_mp.find(fd64) != fd64_to_fd_mp.end();
}
int fd_manager_t::to_fd(fd64_t fd64)
{
int fd_manager_t::to_fd(fd64_t fd64) {
assert(exist(fd64));
return fd64_to_fd_mp[fd64];
}
void fd_manager_t::fd64_close(fd64_t fd64)
{
void fd_manager_t::fd64_close(fd64_t fd64) {
assert(exist(fd64));
int fd = fd64_to_fd_mp[fd64];
fd64_to_fd_mp.erase(fd64);
fd_to_fd64_mp.erase(fd);
if(exist_info(fd64))
{
if (exist_info(fd64)) {
fd_info_mp.erase(fd64);
}
// assert(close(fd)==0);
sock_close(fd);
}
void fd_manager_t::reserve(int n)
{
void fd_manager_t::reserve(int n) {
fd_to_fd64_mp.reserve(n);
fd64_to_fd_mp.reserve(n);
fd_info_mp.reserve(n);
}
u64_t fd_manager_t::create(int fd)
{
u64_t fd_manager_t::create(int fd) {
assert(!fd_exist(fd));
fd64_t fd64 = counter++;
fd_to_fd64_mp[fd] = fd64;
fd64_to_fd_mp[fd64] = fd;
return fd64;
}
fd_manager_t::fd_manager_t()
{
fd_manager_t::fd_manager_t() {
counter = u32_t(-1);
counter += 100;
reserve(10007);
}
fd_info_t & fd_manager_t::get_info(fd64_t fd64)
{
fd_info_t& fd_manager_t::get_info(fd64_t fd64) {
assert(exist(fd64));
return fd_info_mp[fd64];
}
int fd_manager_t::exist_info(fd64_t fd64)
{
int fd_manager_t::exist_info(fd64_t fd64) {
return fd_info_mp.find(fd64) != fd_info_mp.end();
}

4
fd_manager.h
View File

@ -12,8 +12,7 @@
//#include "packet.h"
#include "connection.h"
struct fd_info_t
{
struct fd_info_t {
// ip_port_t ip_port;
conn_info_t *p_conn_info;
};
@ -29,6 +28,7 @@ struct fd_manager_t //conver fd to a uniq 64bit number,avoid fd value conflict
void reserve(int n);
u64_t create(int fd);
fd_manager_t();
private:
u64_t counter;
unordered_map<int, fd64_t> fd_to_fd64_mp;

9
log.cpp Executable file → Normal file
View File

@ -7,11 +7,9 @@ int enable_log_position=0;
int enable_log_color = 1;
void log0(const char* file, const char* function, int line, int level, const char* str, ...) {
if (level > log_level) return;
if (level > log_trace || level < 0) return;
time_t timer;
char buffer[100];
struct tm* tm_info;
@ -39,14 +37,12 @@ void log0(const char * file,const char * function,int line,int level,const char*
// printf(log_color[level]);
fflush(stdout);
if(log_level==log_fatal)
{
if (log_level == log_fatal) {
about_to_exit = 1;
}
}
void log_bare(int level,const char* str, ...)
{
void log_bare(int level, const char* str, ...) {
if (level > log_level) return;
if (level > log_trace || level < 0) return;
if (enable_log_color)
@ -58,5 +54,4 @@ void log_bare(int level,const char* str, ...)
if (enable_log_color)
printf("%s", RESET);
fflush(stdout);
}

7
log.h Executable file → Normal file
View File

@ -2,13 +2,10 @@
#ifndef UDP2RAW_LOG_MYLOG_H_
#define UDP2RAW_LOG_MYLOG_H_
#include "common.h"
using namespace std;
#define RED "\x1B[31m"
#define GRN "\x1B[32m"
#define YEL "\x1B[33m"
@ -18,7 +15,6 @@ using namespace std;
#define WHT "\x1B[37m"
#define RESET "\x1B[0m"
const int log_never = 0;
const int log_fatal = 1;
const int log_error = 2;
@ -35,7 +31,6 @@ extern int log_level;
extern int enable_log_position;
extern int enable_log_color;
#ifdef MY_DEBUG
#define mylog(__first_argu__dummy_abcde__, ...) printf(__VA_ARGS__)
@ -43,12 +38,10 @@ extern int enable_log_color;
#define mylog(...) log0(__FILE__, __FUNCTION__, __LINE__, __VA_ARGS__)
#endif
//#define mylog(__first_argu__dummy_abcde__,...) {;}
void log0(const char* file, const char* function, int line, int level, const char* str, ...);
void log_bare(int level, const char* str, ...);
#endif

42
main.cpp Executable file → Normal file
View File

@ -7,19 +7,16 @@
#include "encrypt.h"
#include "fd_manager.h"
void sigpipe_cb(struct ev_loop *l, ev_signal *w, int revents)
{
void sigpipe_cb(struct ev_loop *l, ev_signal *w, int revents) {
mylog(log_info, "got sigpipe, ignored");
}
void sigterm_cb(struct ev_loop *l, ev_signal *w, int revents)
{
void sigterm_cb(struct ev_loop *l, ev_signal *w, int revents) {
mylog(log_info, "got sigterm, exit");
myexit(0);
}
void sigint_cb(struct ev_loop *l, ev_signal *w, int revents)
{
void sigint_cb(struct ev_loop *l, ev_signal *w, int revents) {
mylog(log_info, "got sigint, exit");
myexit(0);
}
@ -27,8 +24,7 @@ void sigint_cb(struct ev_loop *l, ev_signal *w, int revents)
int client_event_loop();
int server_event_loop();
int main(int argc, char *argv[])
{
int main(int argc, char *argv[]) {
assert(sizeof(unsigned short) == 2);
assert(sizeof(unsigned int) == 4);
assert(sizeof(unsigned long long) == 8);
@ -44,25 +40,22 @@ int main(int argc, char *argv[])
pre_process_arg(argc, argv);
if(program_mode==client_mode)
{
ev_signal signal_watcher_sigpipe;
ev_signal signal_watcher_sigterm;
ev_signal signal_watcher_sigint;
if (program_mode == client_mode) {
struct ev_loop *loop = ev_default_loop(0);
#if !defined(__MINGW32__)
ev_signal signal_watcher_sigpipe;
ev_signal_init(&signal_watcher_sigpipe, sigpipe_cb, SIGPIPE);
ev_signal_start(loop, &signal_watcher_sigpipe);
#endif
ev_signal signal_watcher_sigterm;
ev_signal_init(&signal_watcher_sigterm, sigterm_cb, SIGTERM);
ev_signal_start(loop, &signal_watcher_sigterm);
ev_signal signal_watcher_sigint;
ev_signal_init(&signal_watcher_sigint, sigint_cb, SIGINT);
ev_signal_start(loop, &signal_watcher_sigint);
}
else
{
} else {
#ifdef UDP2RAW_LINUX
signal(SIGINT, signal_handler);
signal(SIGHUP, signal_handler);
@ -73,15 +66,11 @@ int main(int argc, char *argv[])
mylog(log_fatal, "server mode not supported in multi-platform version\n");
myexit(-1);
#endif
}
#if !defined(__MINGW32__)
if(geteuid() != 0)
{
if (geteuid() != 0) {
mylog(log_warn, "root check failed, it seems like you are using a non-root account. we can try to continue, but it may fail. If you want to run udp2raw as non-root, you have to add iptables rule manually, and grant udp2raw CAP_NET_RAW capability, check README.md in repo for more info.\n");
}
else
{
} else {
mylog(log_warn, "you can run udp2raw with non-root account for better security. check README.md in repo for more info.\n");
}
#endif
@ -102,12 +91,9 @@ int main(int argc, char *argv[])
init_raw_socket();
#endif
if(program_mode==client_mode)
{
if (program_mode == client_mode) {
client_event_loop();
}
else
{
} else {
#ifdef UDP2RAW_LINUX
server_event_loop();
#else

45
makefile
View File

@ -2,9 +2,11 @@ cc_cross=/home/wangyu/Desktop/arm-2014.05/bin/arm-none-linux-gnueabi-g++
cc_local=g++
cc_mips24kc_be=/toolchains/lede-sdk-17.01.2-ar71xx-generic_gcc-5.4.0_musl-1.1.16.Linux-x86_64/staging_dir/toolchain-mips_24kc_gcc-5.4.0_musl-1.1.16/bin/mips-openwrt-linux-musl-g++
cc_mips24kc_le=/toolchains/lede-sdk-17.01.2-ramips-mt7621_gcc-5.4.0_musl-1.1.16.Linux-x86_64/staging_dir/toolchain-mipsel_24kc_gcc-5.4.0_musl-1.1.16/bin/mipsel-openwrt-linux-musl-g++
cc_arm= /toolchains/arm-2014.05/bin/arm-none-linux-gnueabi-g++
cc_arm= /toolchains/lede-sdk-17.01.2-bcm53xx_gcc-5.4.0_musl-1.1.16_eabi.Linux-x86_64/staging_dir/toolchain-arm_cortex-a9_gcc-5.4.0_musl-1.1.16_eabi/bin/arm-openwrt-linux-c++
cc_mingw_cross=i686-w64-mingw32-g++-posix
cc_mac_cross=o64-clang++ -stdlib=libc++
cc_x86=/toolchains/lede-sdk-17.01.2-x86-generic_gcc-5.4.0_musl-1.1.16.Linux-x86_64/staging_dir/toolchain-i386_pentium4_gcc-5.4.0_musl-1.1.16/bin/i486-openwrt-linux-c++
cc_amd64=/toolchains/lede-sdk-17.01.2-x86-64_gcc-5.4.0_musl-1.1.16.Linux-x86_64/staging_dir/toolchain-x86_64_gcc-5.4.0_musl-1.1.16/bin/x86_64-openwrt-linux-c++
#cc_bcm2708=/home/wangyu/raspberry/tools/arm-bcm2708/gcc-linaro-arm-linux-gnueabihf-raspbian/bin/arm-linux-gnueabihf-g++
@ -19,7 +21,6 @@ PCAP="-lpcap"
MP="-DUDP2RAW_MP"
NAME=udp2raw
TARGETS=amd64 arm amd64_hw_aes arm_asm_aes mips24kc_be mips24kc_be_asm_aes x86 x86_asm_aes mips24kc_le mips24kc_le_asm_aes
@ -37,7 +38,7 @@ all:git_version
#dynamic link
dynamic: git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -O3
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -O2
#targes for general cross compile
@ -56,33 +57,33 @@ fast: git_version
${cc_local} -o ${NAME} -I. ${SOURCES} ${FLAGS} -lrt -ggdb
debug: git_version
rm -f ${NAME}
${cc_local} -o ${NAME} -I. ${SOURCES} ${FLAGS} -lrt -Wformat-nonliteral -D MY_DEBUG
${cc_local} -o ${NAME} -I. ${SOURCES} ${FLAGS} -lrt -Wformat-nonliteral -D MY_DEBUG -ggdb
debug2: git_version
rm -f ${NAME}
${cc_local} -o ${NAME} -I. ${SOURCES} ${FLAGS} -lrt -Wformat-nonliteral -ggdb
${cc_local} -o ${NAME} -I. ${SOURCES} ${FLAGS} -lrt -Wformat-nonliteral -ggdb -fsanitize=address
#targets only for 'make release'
mips24kc_be: git_version
${cc_mips24kc_be} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -lgcc_eh -static -O3
${cc_mips24kc_be} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -lgcc_eh -static -O2
mips24kc_be_asm_aes: git_version
${cc_mips24kc_be} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -lgcc_eh -static -O3 lib/aes_acc/asm/mips_be.S
${cc_mips24kc_be} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -lgcc_eh -static -O2 lib/aes_acc/asm/mips_be.S
mips24kc_le: git_version
${cc_mips24kc_le} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -lgcc_eh -static -O3
${cc_mips24kc_le} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -lgcc_eh -static -O2
mips24kc_le_asm_aes: git_version
${cc_mips24kc_le} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -lgcc_eh -static -O3 lib/aes_acc/asm/mips.S
${cc_mips24kc_le} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -lgcc_eh -static -O2 lib/aes_acc/asm/mips.S
amd64:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -static -O3
${cc_amd64} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -static -O2 -lgcc_eh -ggdb
amd64_hw_aes:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -static -O3 lib/aes_acc/asm/x64.S
${cc_amd64} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -static -O2 lib/aes_acc/asm/x64.S -lgcc_eh -ggdb
x86:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -static -O3 -m32
${cc_x86} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -static -O2 -lgcc_eh -ggdb
x86_asm_aes:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -static -O3 -m32 lib/aes_acc/asm/x86.S
${cc_x86} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -static -O2 lib/aes_acc/asm/x86.S -lgcc_eh -ggdb
arm:git_version
${cc_arm} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -static -O3
${cc_arm} -o ${NAME}_$@ -I. ${SOURCES} ${FLAGS} -lrt -static -O2 -lgcc_eh
arm_asm_aes:git_version
${cc_arm} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -static -O3 lib/aes_acc/asm/arm.S
${cc_arm} -o ${NAME}_$@ -I. ${SOURCES_AES_ACC} ${FLAGS} -lrt -static -O2 lib/aes_acc/asm/arm.S -lgcc_eh
release: ${TARGETS}
cp git_version.h version.txt
@ -90,22 +91,22 @@ release: ${TARGETS}
#targets for multi-platform version (native compile)
cygwin:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} pcap_wrapper.cpp ${FLAGS} -lrt -ggdb -static -O2 -D_GNU_SOURCE
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} pcap_wrapper.cpp ${FLAGS} -lrt -ggdb -static -O2 -D_GNU_SOURCE ${MP}
mingw:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} pcap_wrapper.cpp ${FLAGS} -ggdb -static -O2 -lws2_32
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} pcap_wrapper.cpp ${FLAGS} -ggdb -static -O2 -lws2_32 ${MP}
mingw_wepoll:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES0} pcap_wrapper.cpp ${FLAGS} -ggdb -static -O2 -DNO_LIBEV_EMBED -D_WIN32 -lev -lws2_32
${cc_local} -o ${NAME}_$@ -I. ${SOURCES0} pcap_wrapper.cpp ${FLAGS} -ggdb -static -O2 -DNO_LIBEV_EMBED -D_WIN32 -lev -lws2_32 ${MP}
linux:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${PCAP} ${FLAGS} -lrt -ggdb -static -O2
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${PCAP} ${FLAGS} -lrt -ggdb -static -O2 ${MP}
freebsd:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${PCAP} ${FLAGS} -lrt -ggdb -static -O2
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${PCAP} ${FLAGS} -lrt -ggdb -static -libverbs -O2 ${MP}
mac:git_version
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${PCAP} ${FLAGS} -ggdb -O2
${cc_local} -o ${NAME}_$@ -I. ${SOURCES} ${PCAP} ${FLAGS} -ggdb -O2 ${MP}
#targets for multi-platform version (cross compile)
@ -120,7 +121,7 @@ mac_cross:git_version
release_mp:${TARGETS_MP}
cp git_version.h version.txt
tar -zcvf ${NAME}_mp_binaries.tar.gz ${NAME}_mp.exe ${NAME}_mp_wepoll.exe ${NAME}_mp_mac
tar -zcvf ${NAME}_mp_binaries.tar.gz ${NAME}_mp.exe ${NAME}_mp_wepoll.exe ${NAME}_mp_mac version.txt
clean:

603
misc.cpp
View File

File diff suppressed because it is too large Load Diff

32
misc.h
View File

@ -8,7 +8,6 @@
#ifndef MISC_H_
#define MISC_H_
#include "common.h"
#include "log.h"
#include "network.h"
@ -26,7 +25,6 @@ extern int enable_dns_resolve;
extern int ttl_value;
const u32_t max_handshake_conn_num = 10000;
const u32_t max_ready_conn_num = 1000;
const u32_t anti_replay_window_size = 4000;
@ -45,7 +43,6 @@ const int conn_clear_min=1;
const u32_t conv_clear_interval = 1000; // ms
const u32_t conn_clear_interval = 1000; // ms
const i32_t max_fail_time = 0; // disable
const u32_t heartbeat_interval = 600; // ms
@ -63,14 +60,25 @@ const uint32_t server_conn_timeout=conv_timeout+60000;//ms. this should be 60s+
const u32_t iptables_rule_keep_interval = 20; // unit: second;
enum server_current_state_t {server_idle=0,server_handshake1,server_ready}; //server state machine
enum client_current_state_t {client_idle=0,client_tcp_handshake,client_handshake1,client_handshake2,client_ready,client_tcp_handshake_dummy};//client state machine
enum server_current_state_t { server_idle = 0,
server_handshake1,
server_ready }; // server state machine
enum client_current_state_t { client_idle = 0,
client_tcp_handshake,
client_handshake1,
client_handshake2,
client_ready,
client_tcp_handshake_dummy }; // client state machine
enum raw_mode_t{mode_faketcp=0,mode_udp,mode_icmp,mode_end};
enum program_mode_t {unset_mode=0,client_mode,server_mode};
enum raw_mode_t { mode_faketcp = 0,
mode_udp,
mode_icmp,
mode_end };
enum program_mode_t { unset_mode = 0,
client_mode,
server_mode };
union current_state_t
{
union current_state_t {
server_current_state_t server_current_state;
client_current_state_t client_current_state;
};
@ -99,7 +107,6 @@ extern int fail_time_counter;//determine if the max_fail_time is reached
extern int epoll_trigger_counter; // for debug only
extern int debug_flag; // for debug only
extern int simple_rule; // deprecated.
extern int keep_rule; // whether to monitor the iptables rule periodly,re-add if losted
extern int auto_add_iptables_rule; // if -a is set
@ -113,7 +120,6 @@ extern int debug_resend; // debug only
extern char key_string[1000]; // -k option
extern char fifo_file[1000];
extern raw_mode_t raw_mode;
extern u32_t raw_ip_version;
@ -124,11 +130,9 @@ extern int about_to_exit;
extern int socket_buf_size;
extern pthread_t keep_thread;
extern int keep_thread_running;
int process_lower_level_arg();
void print_help();
void iptables_rule();
@ -146,8 +150,6 @@ int iptables_gen_add(const char * s,u32_t const_id);
int iptables_rule_init(const char *s, u32_t const_id, int keep);
int keep_iptables_rule();
void signal_handler(int sig);
#endif /* MISC_H_ */

1
my_ev.h
View File

@ -2,4 +2,3 @@
#include "my_ev_common.h"
#include "ev.h"

5
my_ev_common.h
View File

@ -1,6 +1,8 @@
#define EV_STANDALONE 1
#define EV_COMMON void *data; unsigned long long u64;
#define EV_COMMON \
void *data; \
unsigned long long u64;
#define EV_COMPAT3 0
//#include <wepoll.h>
@ -15,4 +17,3 @@
#endif
//#define EV_VERIFY 2

962
network.cpp
View File

File diff suppressed because it is too large Load Diff

37
network.h
View File

@ -47,8 +47,7 @@ extern int send_with_pcap;
extern int pcap_header_captured;
extern int pcap_header_buf[buf_len];
struct icmphdr
{
struct icmphdr {
uint8_t type;
uint8_t code;
uint16_t check_sum;
@ -57,8 +56,7 @@ struct icmphdr
};
#endif
struct my_iphdr
{
struct my_iphdr {
#ifdef UDP2RAW_LITTLE_ENDIAN
unsigned char ihl : 4;
unsigned char version : 4;
@ -78,11 +76,8 @@ struct my_iphdr
/*The options start here. */
};
struct my_udphdr
{
/*__extension__*/ union
{
struct my_udphdr {
/*__extension__*/ union {
struct
{
u_int16_t uh_sport; /* source port */
@ -100,11 +95,8 @@ struct my_udphdr
};
};
struct my_tcphdr
{
/*__extension__*/ union
{
struct my_tcphdr {
/*__extension__*/ union {
struct
{
u_int16_t th_sport; /* source port */
@ -163,8 +155,7 @@ struct my_tcphdr
};
};
struct my_ip6hdr
{
struct my_ip6hdr {
#ifdef UDP2RAW_LITTLE_ENDIAN
uint8_t traffic_class_high : 4;
uint8_t version : 4;
@ -185,8 +176,7 @@ struct my_ip6hdr
struct in6_addr dst;
};
struct my_icmphdr
{
struct my_icmphdr {
uint8_t type;
uint8_t code;
uint16_t check_sum;
@ -215,7 +205,6 @@ struct packet_info_t //todo change this to union
{
uint8_t protocol;
// u32_t src_ip;
// u32_t dst_ip;
my_ip_t new_src_ip;
@ -233,22 +222,20 @@ struct packet_info_t //todo change this to union
u32_t ts, ts_ack;
uint16_t my_icmp_seq;
bool has_ts;
i32_t data_len;
#ifdef UDP2RAW_LINUX
sockaddr_ll addr_ll;
#endif
i32_t data_len;
packet_info_t();
};
struct raw_info_t
{
struct raw_info_t {
packet_info_t send_info;
packet_info_t recv_info;
// int last_send_len;
@ -262,7 +249,6 @@ struct raw_info_t
}; // g_raw_info;
int init_raw_socket();
void init_filter(int port);
@ -321,5 +307,4 @@ int after_send_raw0(raw_info_t &raw_info);
int after_recv_raw0(raw_info_t &raw_info);
#endif /* NETWORK_H_ */

34
pcap_wrapper.cpp
View File

@ -32,26 +32,23 @@ char* (*pcap_lookupdev)(char *)=0;
int (*pcap_findalldevs)(pcap_if_t **, char *) = 0;
struct init_pcap_t
{
init_pcap_t()
{
struct init_pcap_t {
init_pcap_t() {
init_pcap();
}
} do_it;
static void init_npcap_dll_path()
{
BOOL(WINAPI *SetDllDirectory)(LPCTSTR);
static void init_npcap_dll_path() {
BOOL(WINAPI * SetDllDirectory)
(LPCTSTR);
char sysdir_name[512];
int len;
SetDllDirectory = (BOOL(WINAPI *)(LPCTSTR))GetProcAddress(GetModuleHandle("kernel32.dll"), "SetDllDirectoryA");
if (SetDllDirectory == NULL) {
printf("Error in SetDllDirectory\n");
}
else {
} else {
len = GetSystemDirectory(sysdir_name, 480); // be safe
if (!len)
printf("Error in GetSystemDirectory (%d)\n", (int)GetLastError());
@ -61,24 +58,22 @@ static void init_npcap_dll_path()
}
}
#define EXPORT_FUN(XXX) do{ XXX= (__typeof__(XXX)) GetProcAddress(wpcap, #XXX); }while(0)
int init_pcap()
{
#define EXPORT_FUN(XXX) \
do { \
XXX = (__typeof__(XXX))GetProcAddress(wpcap, #XXX); \
} while (0)
int init_pcap() {
HMODULE wpcap = LoadLibrary("wpcap.dll");
if(wpcap!=0)
{
if (wpcap != 0) {
printf("using system32/wpcap.dll\n");
}
else
{
} else {
init_npcap_dll_path();
// SetDllDirectory("C:\\Windows\\System32\\Npcap\\");
wpcap = LoadLibrary("wpcap.dll");
if (wpcap != 0)
printf("using system32/npcap/wpcap.dll\n");
}
if(wpcap==0)
{
if (wpcap == 0) {
printf("cant not open wpcap.dll, make sure winpcap/npcap is installed\n");
exit(-1);
}
@ -121,5 +116,4 @@ int init_pcap()
//pcap_loop = (__typeof__(pcap_loop))GetProcAddress(wpcap, "pcap_loop");
*/
return 0;
}

20
pcap_wrapper.h
View File

@ -7,14 +7,12 @@
//#include <sys/time.h>
//#include <stdint.h>
struct bpf_program
{
char a[2000];
struct bpf_program {
char a[4096];
};
struct pcap_t
{
char a[2000];
struct pcap_t {
char a[4096];
};
typedef unsigned int bpf_u_int32;
@ -36,7 +34,6 @@ typedef enum {
PCAP_D_OUT
} pcap_direction_t;
struct pcap_addr {
struct pcap_addr *next;
struct sockaddr *addr; /* address */
@ -56,11 +53,8 @@ struct pcap_if {
typedef struct pcap_if pcap_if_t;
typedef struct pcap_addr pcap_addr_t;
typedef unsigned char u_char;
#define PCAP_ERRBUF_SIZE 256
#define DLT_NULL 0 /* BSD loopback encapsulation */
@ -112,16 +106,12 @@ extern char* (*pcap_lookupdev)(char *);
extern int (*pcap_findalldevs)(pcap_if_t **, char *);
inline int pcap_set_immediate_mode(pcap_t *,int)
{
inline int pcap_set_immediate_mode(pcap_t *, int) {
return 0;
}
//#ifdef __cplusplus
//}
//#endif
int init_pcap();

294
server.cpp
View File

@ -19,7 +19,7 @@
int server_on_timer_multi(conn_info_t &conn_info) // for server. called when a timer is ready in epoll.for server,there will be one timer for every connection
// there is also a global timer for server,but its not handled here
{
char ip_port[40];
char ip_port[max_addr_len];
// u32_t ip=conn_info.raw_info.send_info.dst_ip;
// u32_t port=conn_info.raw_info.send_info.dst_port;
@ -34,9 +34,7 @@ int server_on_timer_multi(conn_info_t &conn_info) //for server. called when a t
assert(conn_info.state.server_current_state == server_ready);
if(conn_info.state.server_current_state==server_ready)
{
if (conn_info.state.server_current_state == server_ready) {
conn_info.blob->conv_manager.s.clear_inactive(ip_port);
/*
if( get_current_time()-conn_info.last_hb_recv_time>heartbeat_timeout )
@ -49,10 +47,10 @@ int server_on_timer_multi(conn_info_t &conn_info) //for server. called when a t
mylog(log_info,"changed state to server_nothing\n");
return 0;
}*/ //dont need to do this at server,conn_manger will clear expired connections
}*/
// dont need to do this at server,conn_manger will clear expired connections
if(get_current_time()-conn_info.last_hb_sent_time<heartbeat_interval)
{
if (get_current_time() - conn_info.last_hb_sent_time < heartbeat_interval) {
return 0;
}
@ -63,19 +61,15 @@ int server_on_timer_multi(conn_info_t &conn_info) //for server. called when a t
conn_info.last_hb_sent_time = get_current_time();
mylog(log_debug, "heart beat sent<%x,%x>\n", conn_info.my_id, conn_info.oppsite_id);
}
else
{
} else {
mylog(log_fatal, "this shouldnt happen!\n");
myexit(-1);
}
return 0;
}
int server_on_raw_recv_ready(conn_info_t &conn_info, char *ip_port, char type, char *data, int data_len) // called while the state for a connection is server_ready
// receives data and heart beat by recv_safer.
{
raw_info_t &raw_info = conn_info.raw_info;
packet_info_t &send_info = conn_info.raw_info.send_info;
packet_info_t &recv_info = conn_info.raw_info.recv_info;
@ -83,7 +77,6 @@ int server_on_raw_recv_ready(conn_info_t &conn_info,char * ip_port,char type,cha
// sprintf(ip_port,"%s:%d",my_ntoa(recv_info.src_ip),recv_info.src_port);
/*
if (recv_info.src_ip != send_info.dst_ip
|| recv_info.src_port != send_info.dst_port) {
@ -96,15 +89,12 @@ int server_on_raw_recv_ready(conn_info_t &conn_info,char * ip_port,char type,cha
mylog(log_debug, "[%s][hb]received hb \n", ip_port);
conn_info.last_hb_recv_time = get_current_time();
return 0;
} else if (type== 'd' && data_len >=int( sizeof(u32_t) ))
{
} else if (type == 'd' && data_len >= int(sizeof(u32_t))) {
// u32_t tmp_conv_id = ntohl(*((u32_t *) &data[0]));
my_id_t tmp_conv_id;
memcpy(&tmp_conv_id, &data[0], sizeof(tmp_conv_id));
tmp_conv_id = ntohl(tmp_conv_id);
if (hb_mode == 0)
conn_info.last_hb_recv_time = get_current_time();
@ -173,8 +163,6 @@ int server_on_raw_recv_ready(conn_info_t &conn_info,char * ip_port,char type,cha
conn_info.blob->conv_manager.s.insert_conv(tmp_conv_id, new_udp_fd64);
// assert(conn_manager.udp_fd_mp.find(new_udp_fd)==conn_manager.udp_fd_mp.end());
// conn_manager.udp_fd_mp[new_udp_fd] = &conn_info;
@ -183,9 +171,6 @@ int server_on_raw_recv_ready(conn_info_t &conn_info,char * ip_port,char type,cha
mylog(log_info, "[%s]new conv conv_id=%x, assigned fd=%d\n", ip_port,
tmp_conv_id, new_udp_fd);
}
fd64_t fd64 = conn_info.blob->conv_manager.s.find_data_by_conv(tmp_conv_id);
@ -220,12 +205,10 @@ int server_on_raw_recv_pre_ready(conn_info_t &conn_info,char * ip_port,u32_t tmp
mylog(log_info, "[%s]received handshake oppsite_id:%x my_id:%x\n", ip_port, conn_info.oppsite_id, conn_info.my_id);
mylog(log_info, "[%s]oppsite const_id:%x \n", ip_port, tmp_oppsite_const_id);
if(conn_manager.const_id_mp.find(tmp_oppsite_const_id)==conn_manager.const_id_mp.end())
{
if (conn_manager.const_id_mp.find(tmp_oppsite_const_id) == conn_manager.const_id_mp.end()) {
// conn_manager.const_id_mp=
if(conn_manager.ready_num>=max_ready_conn_num)
{
if (conn_manager.ready_num >= max_ready_conn_num) {
mylog(log_info, "[%s]max_ready_conn_num,cant turn to ready\n", ip_port);
conn_info.state.server_current_state = server_idle;
return 0;
@ -237,7 +220,6 @@ int server_on_raw_recv_pre_ready(conn_info_t &conn_info,char * ip_port,u32_t tmp
conn_manager.ready_num++;
conn_manager.const_id_mp[tmp_oppsite_const_id] = &conn_info;
// conn_info.last_state_time=get_current_time(); //dont change this!!!!!!!!!!!!!!!!!!!!!!!!!
// conn_manager.current_ready_ip=ip;
@ -265,7 +247,6 @@ int server_on_raw_recv_pre_ready(conn_info_t &conn_info,char * ip_port,u32_t tmp
// assert(conn_manager.timer_fd_mp.find(new_timer_fd)==conn_manager.timer_fd_mp.end());
// conn_manager.timer_fd_mp[new_timer_fd] = &conn_info;//pack_u64(ip,port);
// timer_fd_mp[new_timer_fd]
/*
if(oppsite_const_id!=0&&tmp_oppsite_const_id!=oppsite_const_id) //TODO MOVE TO READY
@ -274,28 +255,25 @@ int server_on_raw_recv_pre_ready(conn_info_t &conn_info,char * ip_port,u32_t tmp
conv_manager.clear();
}*/
// oppsite_const_id=tmp_oppsite_const_id;
}
else
{
} else {
conn_info_t &ori_conn_info = *conn_manager.const_id_mp[tmp_oppsite_const_id];
if(ori_conn_info.state.server_current_state==server_ready)
{
if(conn_info.last_state_time<ori_conn_info.last_state_time)
{
if (ori_conn_info.state.server_current_state == server_ready) {
if (conn_info.last_state_time < ori_conn_info.last_state_time) {
mylog(log_info, "[%s]conn_info.last_state_time<ori_conn_info.last_state_time. ignored new handshake\n", ip_port);
conn_info.state.server_current_state = server_idle;
conn_info.oppsite_const_id = 0;
return 0;
}
address_t addr1;addr1.from_ip_port_new(raw_ip_version,&ori_conn_info.raw_info.recv_info.new_src_ip,ori_conn_info.raw_info.recv_info.src_port);
address_t addr1;
addr1.from_ip_port_new(raw_ip_version, &ori_conn_info.raw_info.recv_info.new_src_ip, ori_conn_info.raw_info.recv_info.src_port);
if (!conn_manager.exist(addr1)) // TODO remove this
{
mylog(log_fatal, "[%s]this shouldnt happen\n", ip_port);
myexit(-1);
}
address_t addr2;addr2.from_ip_port_new(raw_ip_version,&conn_info.raw_info.recv_info.new_src_ip,conn_info.raw_info.recv_info.src_port);
address_t addr2;
addr2.from_ip_port_new(raw_ip_version, &conn_info.raw_info.recv_info.new_src_ip, conn_info.raw_info.recv_info.src_port);
if (!conn_manager.exist(addr2)) // TODO remove this
{
mylog(log_fatal, "[%s]this shouldnt happen2\n", ip_port);
@ -307,10 +285,8 @@ int server_on_raw_recv_pre_ready(conn_info_t &conn_info,char * ip_port,u32_t tmp
p = p_ori;
p_ori = tmp;
mylog(log_info, "[%s]grabbed a connection\n", ip_port);
// ori_conn_info.state.server_current_state=server_ready;
ori_conn_info.recover(conn_info);
@ -323,14 +299,10 @@ int server_on_raw_recv_pre_ready(conn_info_t &conn_info,char * ip_port,u32_t tmp
ori_conn_info.last_hb_recv_time = get_current_time();
conn_info.state.server_current_state = server_idle;
conn_info.oppsite_const_id = 0;
}
else
{
} else {
mylog(log_fatal, "[%s]this should never happen\n", ip_port);
myexit(-1);
}
@ -350,8 +322,7 @@ int server_on_raw_recv_handshake1(conn_info_t &conn_info,char * ip_port,char * d
// char ip_port[40];
// sprintf(ip_port,"%s:%d",my_ntoa(ip),port);
if(data_len<int( 3*sizeof(my_id_t)))
{
if (data_len < int(3 * sizeof(my_id_t))) {
mylog(log_debug, "[%s] data_len=%d too short to be a handshake\n", ip_port, data_len);
return -1;
}
@ -367,22 +338,18 @@ int server_on_raw_recv_handshake1(conn_info_t &conn_info,char * ip_port,char * d
if (tmp_my_id == 0) // received init handshake again
{
if(raw_mode==mode_faketcp)
{
if (raw_mode == mode_faketcp) {
send_info.seq = recv_info.ack_seq;
send_info.ack_seq = recv_info.seq + raw_info.recv_info.data_len;
send_info.ts_ack = recv_info.ts;
}
if(raw_mode==mode_icmp)
{
if (raw_mode == mode_icmp) {
send_info.my_icmp_seq = recv_info.my_icmp_seq;
}
send_handshake(raw_info, conn_info.my_id, tmp_oppsite_id, const_id); //////////////send
mylog(log_info, "[%s]changed state to server_handshake1,my_id is %x\n", ip_port, conn_info.my_id);
}
else if(tmp_my_id==conn_info.my_id)
{
} else if (tmp_my_id == conn_info.my_id) {
conn_info.oppsite_id = tmp_oppsite_id;
// id_t tmp_oppsite_const_id=ntohl(* ((u32_t *)&data[sizeof(id_t)*2]));
@ -390,30 +357,24 @@ int server_on_raw_recv_handshake1(conn_info_t &conn_info,char * ip_port,char * d
memcpy(&tmp_oppsite_const_id, &data[sizeof(my_id_t) * 2], sizeof(tmp_oppsite_const_id));
tmp_oppsite_const_id = ntohl(tmp_oppsite_const_id);
if(raw_mode==mode_faketcp)
{
if (raw_mode == mode_faketcp) {
send_info.seq = recv_info.ack_seq;
send_info.ack_seq = recv_info.seq + raw_info.recv_info.data_len;
send_info.ts_ack = recv_info.ts;
}
if(raw_mode==mode_icmp)
{
if (raw_mode == mode_icmp) {
send_info.my_icmp_seq = recv_info.my_icmp_seq;
}
server_on_raw_recv_pre_ready(conn_info, ip_port, tmp_oppsite_const_id);
}
else
{
} else {
mylog(log_debug, "[%s]invalid my_id %x,my_id is %x\n", ip_port, tmp_my_id, conn_info.my_id);
}
return 0;
}
int server_on_recv_safer_multi(conn_info_t &conn_info,char type,char *data,int data_len)
{
int server_on_recv_safer_multi(conn_info_t &conn_info, char type, char *data, int data_len) {
return 0;
}
int server_on_raw_recv_multi() // called when server received an raw packet
@ -424,8 +385,7 @@ int server_on_raw_recv_multi() //called when server received an raw packet
packet_info_t &peek_info = peek_raw_info.recv_info;
mylog(log_trace, "got a packet\n");
if (pre_recv_raw_packet() < 0) return -1;
if(peek_raw(peek_raw_info)<0)
{
if (peek_raw(peek_raw_info) < 0) {
discard_raw_packet();
// recv(raw_recv_fd, 0,0, 0 );//
// struct sockaddr saddr;
@ -433,33 +393,33 @@ int server_on_raw_recv_multi() //called when server received an raw packet
/// recvfrom(raw_recv_fd, 0,0, 0 ,&saddr , &saddr_size);//
mylog(log_trace, "peek_raw failed\n");
return -1;
}else
{
} else {
mylog(log_trace, "peek_raw success\n");
}
// u32_t ip=peek_info.src_ip;uint16_t port=peek_info.src_port;
int data_len; char *data;
int data_len;
char *data;
address_t addr;
addr.from_ip_port_new(raw_ip_version, &peek_info.new_src_ip, peek_info.src_port);
char ip_port[40];
char ip_port[max_addr_len];
addr.to_str(ip_port);
// sprintf(ip_port,"%s:%d",my_ntoa(ip),port);
mylog(log_trace, "[%s]peek_raw\n", ip_port);
if(raw_mode==mode_faketcp&&peek_info.syn==1)
{
if(!conn_manager.exist(addr)||conn_manager.find_insert(addr).state.server_current_state!=server_ready)
{//reply any syn ,before state become ready
if (raw_mode == mode_faketcp && peek_info.syn == 1) {
if (!conn_manager.exist(addr) || conn_manager.find_insert(addr).state.server_current_state != server_ready) { // reply any syn ,before state become ready
raw_info_t tmp_raw_info;
if(recv_raw0(tmp_raw_info,data,data_len)<0)
{
if (recv_raw0(tmp_raw_info, data, data_len) < 0) {
return 0;
}
if (data_len >= max_data_len + 1) {
mylog(log_debug, "data_len=%d >= max_data_len+1,ignored", data_len);
return -1;
}
if (use_tcp_dummy_socket != 0)
return 0;
raw_info_t &raw_info = tmp_raw_info;
@ -472,13 +432,11 @@ int server_on_raw_recv_multi() //called when server received an raw packet
send_info.dst_port = recv_info.src_port;
send_info.new_dst_ip = recv_info.new_src_ip;
if(lower_level)
{
if (lower_level) {
handle_lower_level(raw_info);
}
if(data_len==0&&raw_info.recv_info.syn==1&&raw_info.recv_info.ack==0)
{
if (data_len == 0 && raw_info.recv_info.syn == 1 && raw_info.recv_info.ack == 0) {
send_info.ack_seq = recv_info.seq + 1;
send_info.psh = 0;
@ -490,18 +448,14 @@ int server_on_raw_recv_multi() //called when server received an raw packet
send_raw0(raw_info, 0, 0);
return 0;
}
}
else
{
} else {
discard_raw_packet();
// recv(raw_recv_fd, 0,0,0);
}
return 0;
}
if(!conn_manager.exist(addr))
{
if(conn_manager.mp.size()>=max_handshake_conn_num)
{
if (!conn_manager.exist(addr)) {
if (conn_manager.mp.size() >= max_handshake_conn_num) {
mylog(log_info, "[%s]reached max_handshake_conn_num,ignored new handshake\n", ip_port);
discard_raw_packet();
// recv(raw_recv_fd, 0,0, 0 );//
@ -510,17 +464,13 @@ int server_on_raw_recv_multi() //called when server received an raw packet
raw_info_t tmp_raw_info;
if(raw_mode==mode_icmp)
{
if (raw_mode == mode_icmp) {
tmp_raw_info.send_info.dst_port = tmp_raw_info.send_info.src_port = addr.get_port();
}
if(recv_bare(tmp_raw_info,data,data_len)<0)
{
if (recv_bare(tmp_raw_info, data, data_len) < 0) {
return 0;
}
if(data_len<int( 3*sizeof(my_id_t)))
{
if (data_len < int(3 * sizeof(my_id_t))) {
mylog(log_debug, "[%s]too short to be a handshake\n", ip_port);
return -1;
}
@ -530,8 +480,7 @@ int server_on_raw_recv_multi() //called when server received an raw packet
memcpy(&zero, &data[sizeof(my_id_t)], sizeof(zero));
zero = ntohl(zero);
if(zero!=0)
{
if (zero != 0) {
mylog(log_debug, "[%s]not a invalid initial handshake\n", ip_port);
return -1;
}
@ -548,16 +497,13 @@ int server_on_raw_recv_multi() //called when server received an raw packet
// conn_info.ip_port.ip=ip;
// conn_info.ip_port.port=port;
send_info.new_src_ip = recv_info.new_dst_ip;
send_info.src_port = recv_info.dst_port;
send_info.dst_port = recv_info.src_port;
send_info.new_dst_ip = recv_info.new_src_ip;
if(lower_level)
{
if (lower_level) {
handle_lower_level(raw_info);
}
@ -566,7 +512,6 @@ int server_on_raw_recv_multi() //called when server received an raw packet
conn_info.my_id = get_true_random_number_nz();
mylog(log_info, "[%s]created new conn,state: server_handshake1,my_id is %x\n", ip_port, conn_info.my_id);
conn_info.state.server_current_state = server_handshake1;
@ -576,46 +521,36 @@ int server_on_raw_recv_multi() //called when server received an raw packet
return 0;
}
conn_info_t &conn_info = conn_manager.find_insert(addr); // insert if not exist
packet_info_t &send_info = conn_info.raw_info.send_info;
packet_info_t &recv_info = conn_info.raw_info.recv_info;
raw_info_t &raw_info = conn_info.raw_info;
if(conn_info.state.server_current_state==server_handshake1)
{
if(recv_bare(raw_info,data,data_len)!=0)
{
if (conn_info.state.server_current_state == server_handshake1) {
if (recv_bare(raw_info, data, data_len) != 0) {
return -1;
}
return server_on_raw_recv_handshake1(conn_info, ip_port, data, data_len);
}
if(conn_info.state.server_current_state==server_ready)
{
if (conn_info.state.server_current_state == server_ready) {
vector<char> type_vec;
vector<string> data_vec;
recv_safer_multi(conn_info, type_vec, data_vec);
if(data_vec.empty())
{
if (data_vec.empty()) {
mylog(log_debug, "recv_safer failed!\n");
return -1;
}
for(int i=0;i<(int)type_vec.size();i++)
{
for (int i = 0; i < (int)type_vec.size(); i++) {
char type = type_vec[i];
char *data = (char *)data_vec[i].c_str(); // be careful, do not append data to it
int data_len = data_vec[i].length();
server_on_raw_recv_ready(conn_info, ip_port, type, data, data_len);
}
return 0;
}
if(conn_info.state.server_current_state==server_idle)
{
if (conn_info.state.server_current_state == server_idle) {
discard_raw_packet();
// recv(raw_recv_fd, 0,0, 0 );//
return 0;
@ -625,8 +560,7 @@ int server_on_raw_recv_multi() //called when server received an raw packet
return -1;
}
int server_on_udp_recv(conn_info_t &conn_info,fd64_t fd64)
{
int server_on_udp_recv(conn_info_t &conn_info, fd64_t fd64) {
char buf[buf_len];
if (conn_info.state.server_current_state != server_ready) // TODO remove this for peformance
@ -647,82 +581,64 @@ int server_on_udp_recv(conn_info_t &conn_info,fd64_t fd64)
mylog(log_trace, "received a packet from udp_fd,len:%d\n", recv_len);
if(recv_len==max_data_len+1)
{
if (recv_len == max_data_len + 1) {
mylog(log_warn, "huge packet, data_len > %d,dropped\n", max_data_len);
return -1;
}
if(recv_len<0)
{
if (recv_len < 0) {
mylog(log_debug, "udp fd,recv_len<0 continue,%s\n", strerror(errno));
return -1;
}
if(recv_len>=mtu_warn)
{
if (recv_len >= mtu_warn) {
mylog(log_warn, "huge packet,data len=%d (>=%d).strongly suggested to set a smaller mtu at upper level,to get rid of this warn\n ", recv_len, mtu_warn);
}
// conn_info.conv_manager->update_active_time(conv_id); server dosnt update from upd side,only update from raw side. (client updates at both side)
if(conn_info.state.server_current_state==server_ready)
{
if (conn_info.state.server_current_state == server_ready) {
send_data_safer(conn_info, buf, recv_len, conv_id);
// send_data(g_packet_info_send,buf,recv_len,my_id,oppsite_id,conv_id);
mylog(log_trace, "send_data_safer ,sent !!\n");
}
return 0;
}
int server_event_loop()
{
int server_event_loop() {
char buf[buf_len];
int i, j, k;int ret;
int i, j, k;
int ret;
if(raw_ip_version==AF_INET)
{
if(local_addr.inner.ipv4.sin_addr.s_addr!=0)
{
if (raw_ip_version == AF_INET) {
if (local_addr.inner.ipv4.sin_addr.s_addr != 0) {
bind_addr_used = 1;
bind_addr.v4 = local_addr.inner.ipv4.sin_addr.s_addr;
}
}
else
{
} else {
assert(raw_ip_version == AF_INET6);
char zero_arr[16] = {0};
if(memcmp(&local_addr.inner.ipv6.sin6_addr,zero_arr,16)!=0)
{
if (memcmp(&local_addr.inner.ipv6.sin6_addr, zero_arr, 16) != 0) {
bind_addr_used = 1;
bind_addr.v6 = local_addr.inner.ipv6.sin6_addr;
}
}
// bind_address_uint32=local_ip_uint32;//only server has bind adress,client sets it to zero
if(lower_level)
{
if(lower_level_manual)
{
if (lower_level) {
if (lower_level_manual) {
init_ifindex(if_name, raw_send_fd, ifindex);
mylog(log_info, "we are running at lower-level (manual) mode\n");
}
else
{
} else {
mylog(log_info, "we are running at lower-level (auto) mode\n");
}
}
if(raw_mode==mode_faketcp)
{
if (raw_mode == mode_faketcp) {
bind_fd = socket(local_addr.get_type(), SOCK_STREAM, 0);
}
else if(raw_mode==mode_udp||raw_mode==mode_icmp)//bind an adress to avoid collision,for icmp,there is no port,just bind a udp port
} else if (raw_mode == mode_udp || raw_mode == mode_icmp) // bind an adress to avoid collision,for icmp,there is no port,just bind a udp port
{
bind_fd = socket(local_addr.get_type(), SOCK_DGRAM, 0);
}
@ -734,24 +650,18 @@ int server_event_loop()
// temp_bind_addr.sin_port = local_addr.get_port();
// temp_bind_addr.sin_addr.s_addr = local_addr.inner.ipv4.sin_addr.s_addr;
if (bind(bind_fd, (struct sockaddr*)&local_addr.inner, local_addr.get_len()) !=0)
{
if (bind(bind_fd, (struct sockaddr *)&local_addr.inner, local_addr.get_len()) != 0) {
mylog(log_fatal, "bind fail\n");
myexit(-1);
}
if(raw_mode==mode_faketcp)
{
if(listen(bind_fd, SOMAXCONN) != 0 )
{
if (raw_mode == mode_faketcp) {
if (listen(bind_fd, SOMAXCONN) != 0) {
mylog(log_fatal, "listen fail\n");
myexit(-1);
}
}
// init_raw_socket();
init_filter(local_addr.get_port()); // bpf filter
@ -783,8 +693,7 @@ int server_event_loop()
int fifo_fd = -1;
if(fifo_file[0]!=0)
{
if (fifo_file[0] != 0) {
fifo_fd = create_fifo(fifo_file);
ev.events = EPOLLIN;
ev.data.u64 = fifo_fd;
@ -797,40 +706,32 @@ int server_event_loop()
mylog(log_info, "fifo_file=%s\n", fifo_file);
}
while (1) ////////////////////////
{
if (about_to_exit) myexit(0);
int nfds = epoll_wait(epollfd, events, max_events, 180 * 1000);
if (nfds < 0) { // allow zero
if(errno==EINTR )
{
if (errno == EINTR) {
mylog(log_info, "epoll interrupted by signal,continue\n");
// myexit(0);
}
else
{
} else {
mylog(log_fatal, "epoll_wait return %d,%s\n", nfds, strerror(errno));
myexit(-1);
}
}
int idx;
for (idx = 0; idx < nfds; ++idx)
{
for (idx = 0; idx < nfds; ++idx) {
// mylog(log_debug,"ndfs: %d \n",nfds);
epoll_trigger_counter++;
// printf("%d %d %d %d\n",timer_fd,raw_recv_fd,raw_send_fd,n);
if ((events[idx].data.u64 ) == (u64_t)timer_fd)
{
if ((events[idx].data.u64) == (u64_t)timer_fd) {
if (debug_flag) begin_time = get_current_time();
conn_manager.clear_inactive();
u64_t dummy;
int unused = read(timer_fd, &dummy, 8);
// current_time_rough=get_current_time();
if(debug_flag)
{
if (debug_flag) {
end_time = get_current_time();
mylog(log_debug, "timer_fd,%llu,%llu,%llu\n", begin_time, end_time, end_time - begin_time);
}
@ -838,22 +739,16 @@ int server_event_loop()
mylog(log_trace, "epoll_trigger_counter: %d \n", epoll_trigger_counter);
epoll_trigger_counter = 0;
}
else if (events[idx].data.u64 == (u64_t)raw_recv_fd)
{
} else if (events[idx].data.u64 == (u64_t)raw_recv_fd) {
if (debug_flag) begin_time = get_current_time();
server_on_raw_recv_multi();
if(debug_flag)
{
if (debug_flag) {
end_time = get_current_time();
mylog(log_debug, "raw_recv_fd,%llu,%llu,%llu \n", begin_time, end_time, end_time - begin_time);
}
}
else if (events[idx].data.u64 == (u64_t)fifo_fd)
{
} else if (events[idx].data.u64 == (u64_t)fifo_fd) {
int len = read(fifo_fd, buf, sizeof(buf));
if(len<0)
{
if (len < 0) {
mylog(log_warn, "fifo read failed len=%d,errno=%s\n", len, strerror(errno));
continue;
}
@ -863,13 +758,9 @@ int server_event_loop()
buf[len - 1] = 0;
mylog(log_info, "got data from fifo,len=%d,s=[%s]\n", len, buf);
mylog(log_info, "unknown command\n");
}
else if (events[idx].data.u64>u32_t(-1) )
{
} else if (events[idx].data.u64 > u32_t(-1)) {
fd64_t fd64 = events[idx].data.u64;
if(!fd_manager.exist(fd64))
{
if (!fd_manager.exist(fd64)) {
mylog(log_trace, "fd64 no longer exist\n");
return -1;
}
@ -878,36 +769,29 @@ int server_event_loop()
conn_info_t &conn_info = *p_conn_info;
if (fd64 == conn_info.timer_fd64) //////////timer_fd64
{
if (debug_flag) begin_time = get_current_time();
int fd = fd_manager.to_fd(fd64);
u64_t dummy;
int unused = read(fd, &dummy, 8);
assert(conn_info.state.server_current_state == server_ready); // TODO remove this for peformance
server_on_timer_multi(conn_info);
if(debug_flag)
{
if (debug_flag) {
end_time = get_current_time();
mylog(log_debug, "(events[idx].data.u64 >>32u) == 2u ,%llu,%llu,%llu \n", begin_time, end_time, end_time - begin_time);
}
}
else//udp_fd64
} else // udp_fd64
{
if (debug_flag) begin_time = get_current_time();
server_on_udp_recv(conn_info, fd64);
if(debug_flag)
{
if (debug_flag) {
end_time = get_current_time();
mylog(log_debug, "(events[idx].data.u64 >>32u) == 1u,%lld,%lld,%lld \n", begin_time, end_time, end_time - begin_time);
}
}
}
else
{
} else {
mylog(log_fatal, "unknown fd,this should never happen\n");
myexit(-1);
}
}
}
return 0;